Stoichiometric nucleic acid purification using randomer capture probe libraries

ABSTRACT

This disclosure describes a method of purifying several full-length oligonucleotide targets from corresponding synthesis truncation products, in a way that ensures roughly stoichiometric equality among the targets.

This application claims the benefit of U.S. Provisional Patent Application No. 62/332,778, filed May 6, 2016, the entirety of which is incorporated herein by reference.

BACKGROUND

Technologies for writing (Gene Synthesis), editing (CRISPR/CAS) and reading (Next generation Sequencing-NGS) large collections of nucleic acids requires an enormous (>1000) number of oligonucleotides to be used as building blocks (writing), guides (editing) or hybridization probes and primers for doing highly multiplexed enrichment and sequencing (reading). It is not economical to synthesize, purify, and quantitate each oligonucleotide individually. Companies such as Agilent, NimbleGen, and Twist Biosciences have developed array-based synthesis platforms to allow highly multiplex DNA oligonucleotide synthesis, but the oligonucleotides synthesized by these platforms include truncation products. Because modern oligonucleotide synthesis occurs from 3′ to 5′, most impurity species are truncation oligonucleotide products lacking a number of nucleotides at the 5′ end, followed by species with one or more internal deletions. In single-plex synthesis, these fraction of these impurity products can be reduced through post-synthesis high pressure liquid chromatography (HPLC) or polyacrylamide gel electrophoresis (PAGE) purification, but HPLC and PAGE cannot be used to purify a pool of many different oligonucleotides. Furthermore, HPLC and PAGE are time- and labor-intensive and cannot be easily automated to high throughput. Additionally, even single-plex HPLC and PAGE purification of oligonucleotides result only in below 90% purity of full-length oligonucleotide products.

The concentrations of different oligonucleotides in an array-synthesized pool will vary significantly based on oligonucleotide length, oligonucleotide sequence, and synthesis reagent age and purity. Consequently, oligonucleotides synthesis yields can vary by more than 16-fold from the same quantity of initial synthesis reagents. The variation in oligonucleotide concentrations can adversely affect downstream applications, e.g., in the production of long synthetic genes. In NGS, concentration variations in oligonucleotide pools used for hybrid-capture enrichment result in sequencing biases that cause significant wasted NGS reads.

SUMMARY

In accordance with the present disclosure, there is provided a method for generating a set of precursor nucleotide sequences comprising a target oligonucleotide molecule, wherein the precursor nucleotide sequence comprises a fifth region that comprises the nucleotide sequence of the target oligonucleotide molecule and a fourth region and a third region, wherein at least one of the fourth and third regions differs from any subsequence within the target oligonucleotide, the method comprising:

-   -   (i) calculating for the precursor nucleotide sequence the         standard free energy of hybridization between the precursor         nucleotide sequence and (a) a first oligonucleotide comprising a         second region that is complementary to the third region of the         precursor oligonucleotide sequence, and (b) a first region that         is complementary to the fourth region of the precursor         oligonucleotide sequence;     -   (ii) calculating the standard free energy of a capture reaction         as the standard free energy of hybridization between the         precursor nucleotide sequence and the first oligonucleotide and         the standard free energy of hybridization between the first         oligonucleotide and target oligonucleotide;     -   (iii) rejecting the precursor nucleotide sequence if the         standard free energy of the capture reaction does not meet a         certain criterion; and     -   (iv) repeating steps (i) to (iii) until a set of precursor         nucleotide sequences meets the criteria; and     -   (v) producing the set of precursor nucleotide sequences.         The criteria may be a negative free energy;

In another embodiment, there is provided a method for producing a set pf precursor nucleotide sequences comprising a plurality of barcode sequences, comprising:

-   -   (i) generating a set of precursor nucleotide sequences         comprising each target oligonucleotide molecule, wherein each         precursor nucleotide sequence comprises a third region that is         conserved across all precursor nucleotide sequences, a fourth         region that is unique for each target oligonucleotide molecule,         and an fifth region that comprises the nucleotide sequence of a         target oligonucleotide molecule;     -   (ii) calculating for each precursor nucleotide sequence the         standard free energy of hybridization between the precursor         nucleotide sequence and (a) a first oligonucleotide, comprising         a second region that is complementary to the third region of the         precursor oligonucleotide sequence, and (b) a first region that         is complementary to the fourth region of the precursor         oligonucleotide sequence;     -   (iii) calculating for each precursor nucleotide sequence the         standard free energy of hybridization of folding;     -   (iv) calculating the standard free energy of a capture reaction         as the standard free energy of hybridization between the         precursor nucleotide sequence and the first oligonucleotide and         the standard free energy of folding of the first oligonucleotide         and the standard free energy of folding of the precursor         oligonucleotide;     -   (v) rejecting the set of precursor nucleotide sequences if the         standard free energy of the capture reaction for any precursor         nucleotide sequence exceeds a certain criteria;     -   (vi) repeating steps (i) to (v) until a set of precursor         nucleotide sequences meets the criteria; and     -   (vii) producing said set of precursor nucleotide sequences.

The criteria may be a selected from the group consisting of a maximum range of standard free energies of capture, a standard deviation of standard free energies of capture, and a difference between two ranks in a sorted list. The criteria may be a maximum range of no more than 5 kcal/mol between a lowest standard free energy of capture and a highest standard free energy of capture for the set of precursor nucleotide sequences. The maximum range may be no more than 2 kcal/mol.

In yet another embodiment, there is provided a method for purifying one or multiple target nucleic acid molecules from a sample comprising one or a plurality of species of precursor molecules, wherein each species of precursor molecule comprises an fifth region comprising a target nucleic acid molecule sequence, a fourth region comprising a sequence unique to the species of precursor molecule in the plurality of species of precursor molecules, defined as a barcode sequence of length n, wherein 2″ is greater than or equal to the number of unique target nucleic acid molecule sequences, a third region that is conserved across all precursor molecules, the method comprising:

-   -   contacting the sample with a capture probe library at         temperature and buffer conditions conducive to hybridization;     -   wherein the capture probe library comprises a plurality of         capture probe species, wherein each capture probe species         comprises a first oligonucleotide comprising a first region         comprising a nucleotide sequence of n nucleotides in length and         a second region that is conserved across all capture probe         species, wherein each nucleotide in the nucleotide sequence of n         nucleotides in length is selected from two or more nucleotides         and the first region is unique to each capture probe, and         wherein the second region is complementary to the third region,         and wherein the fourth region of each species of precursor         molecule is complementary to the first region of a species of         precursor molecule;     -   separating the plurality of species of precursor molecules         hybridized to the plurality of capture probe species from the         species of precursor molecules not hybridized to the plurality         of capture probe species;     -   treating the plurality of species of precursor molecules         hybridized to the plurality of capture probe species with a         cleavage agent sufficient to site-specifically cleave the         plurality;     -   of species of precursor molecules at a site to separate the         fifth regions from at least a portion of the third and fourth         regions;     -   recovering the fifth regions from the plurality of capture probe         species and the at least a portion of the third and fourth         regions, and thereby producing a purified target nucleic acid         molecule or molecules.

Each capture probe species may further comprise a second oligonucleotide comprising a ninth region, wherein the ninth region is complementary to the second region. Each first oligonucleotide may further comprise a seventh region, each second oligonucleotide further comprises an eight region, and wherein the seventh region is complementary to the eight region. Each first oligonucleotide further may comprise a chemical moiety, and wherein the separating the plurality of species of precursor molecules hybridized to the plurality of capture probe species comprises surface capture of the chemical moiety. The chemical moiety may be selected from the group consisting of biotin, a thiol, an azide, an alkyne, a primary amine and a lipid. The first nucleotide hybridized with the precursor oligonucleotide may be the preferred ligand of an antibody or other receptor that mediate the surface capture of the complexes.

Recovering the fifth regions from the plurality of capture probe species and the at least a portion of the third and fourth regions may comprise a treatment selected from the group consisting of heating, introducing denaturants, washing with low salinity buffers, and introducing a nuclease. The site-specific cleavage may comprise a treatment selected from the group consisting of changing the temperature, changing the pH, and illuminating the plurality of species of precursor molecules hybridized to the plurality of capture probe species at a specific wavelength. The standard free energies of binding between each first oligonucleotide and a DNA sequence complementary to the entire sequence of the first oligonucleotide may be within 5 kcal/mol of each other. The two or more nucleotides at each nucleotide in the nucleotide sequence of n nucleotides in length maybe A or T, or may be G or C. The two or more nucleotides at each nucleotide in the nucleotide sequence of n nucleotides in length may be G or C for one or more nucleotides in the nucleotide sequence and A or T for one more nucleotides in the nucleotide sequence. The first region may comprise between 3 and 25 nucleotides. n may be between 3 and 60, 3 and 18, or 3 and 10 and not greater than the number of nucleotides in the first region. The first region may further comprise at least one nucleotide in addition to the nucleotide sequence of n nucleotides in length. The second region may further comprise between 8 and 200 nucleotides.

The barcode sequence of each species of precursor molecule is assigned based on a method comprising:

-   -   generating a set of precursor nucleotide sequences comprising         each target oligonucleotide molecule, wherein each precursor         nucleotide sequence comprises a third region that is conserved         across all precursor nucleotide sequences, a fourth region that         is unique for each target oligonucleotide molecule, and an fifth         region that comprises the nucleotide sequence of the target         oligonucleotide molecule;     -   calculating for each precursor nucleotide sequence the standard         free energy of hybridization between the precursor nucleotide         sequence and a first oligonucleotide, comprising a second region         that is complementary to the third region of the precursor         oligonucleotide sequence, and a first region that is         complementary to the fourth region of the precursor         oligonucleotide sequence;     -   calculating for each precursor nucleotide sequence the standard         free energy of hybridization of folding;     -   calculating the standard free energy of a capture reaction as         the standard free energy of hybridization between the precursor         nucleotide sequence and the first oligonucleotide and the         standard free energy of folding of the first oligonucleotide and         the standard free energy of folding of the precursor         oligonucleotide;     -   rejecting the set of precursor nucleotide sequences if the         standard free energy of the capture reaction for any precursor         nucleotide sequence exceeds a certain criteria; and     -   repeating the method until a set of precursor nucleotide         sequences meets the criteria.

In still yet another embodiment, there is provided a capture probe library comprising: a plurality of oligonucleotides comprising a first plurality of oligonucleotides wherein each oligonucleotide of the first plurality of oligonucleotides comprises:

-   -   a first region comprising a first nucleotide sequence comprising         at least 3 variable positions, wherein each variable position         comprises a nucleotide selected from at least two possible         nucleotides,     -   wherein the first nucleotide sequence comprising at least 3         variable positions is unique to each oligonucleotide, and     -   a second region comprising a second nucleotide sequence, wherein         the second nucleotide sequence of the second region is conserved         across each oligonucleotide in the first plurality of         oligonucleotides,     -   A capture probe library comprising:     -   a plurality of oligonucleotides comprising a first plurality of         oligonucleotides and a second plurality of oligonucleotides,         wherein each oligonucleotide in the first plurality of species         of oligonucleotides comprises     -   a first region comprising a nucleotide sequence comprising at         least 3 variable positions, wherein each variable position         comprises a nucleotide selected from at least two possible         nucleotides,     -   wherein the nucleotide sequence comprising at least 3 variable         positions is unique to each species of oligonucleotide, and     -   a second region comprising a nucleotide sequence, wherein the         nucleotide sequence of the second region is conserved across         each oligonucleotide in the first plurality of oligonucleotides,     -   wherein each oligonucleotide in the second plurality of         oligonucleotides comprises a third region, wherein the third         region is complementary to the second region.         The standard free energies of binding between each         oligonucleotide in the first plurality of oligonucleotides and a         DNA sequence complementary to the entire sequence of the         respective oligonucleotide in the first plurality of         oligonucleotides may be within 5 kcal/mol of each other. The at         least two possible nucleotides at each nucleotide in may be A or         T, or may be G or C. The         at least two possible nucleotides at each nucleotide in may be G         or C for one or more nucleotides in the nucleotide sequence and         A or T for one more nucleotides in the nucleotide sequence. The         concentration of a second oligonucleotide may be greater than a         sum of the concentrations of each oligonucleotide of the first         plurality of oligonucleotides. The first region may comprise         between 3 and 25 nucleotides. The number of variable positions         in the first region may be between 3 and 60, between 3 and 18,         or between 3 and 10, and not greater than a total number of         nucleotides in the first region. The first region further may         comprise at least one nucleotide in addition to the at least 3         variable positions. The second region may comprise between 8 and         200 nucleotides. The at least three variable regions may be         contiguous or non-contiguous.

A further embodiment comprise an oligonucleotide library for the multiplexed capture of a set of desired precursor nucleic acid molecules comprising:

-   -   a plurality of species of precursor molecules, wherein each         species of precursor molecule comprises     -   a third region comprising a nucleotide sequence that is         conserved across all species of precursor molecules,     -   a fourth region comprising a barcode sequence comprising 3-60         nucleotides, an fifth region comprising a target nucleic acid         molecule sequence that is unique to the species of precursor         molecule in the plurality of species of precursor molecules,         wherein the barcode sequence of each species of precursor         molecule is different and wherein 2n is greater than or equal to         the number of unique target nucleic acid molecule sequences; and     -   a capture probe library comprising a plurality of capture probe         species, wherein each capture probe species comprises an         oligonucleotide comprising a first region comprising a         nucleotide sequence of n nucleotides in length, a second region         that is conserved across all capture probe species, wherein each         nucleotide in the nucleotide sequence of n nucleotides in length         is selected from two or more nucleotides and the first region is         unique to each capture probe, and wherein the second region is         complementary to the third region, and wherein the fourth region         of each species of precursor molecule is complementary to the         first region of a species of precursor molecule.         The standard free energies of binding between each species of         first oligonucleotide in the plurality of capture probe species         and a DNA sequence complementary to the entire sequence of the         respective species of first oligonucleotide may be within 5         kcal/mol of each other. The two or more nucleotides at each         nucleotide in the nucleotide sequence of n nucleotides in length         may be A or T, or may be G or C. The two or more nucleotides at         each nucleotide in the nucleotide sequence of n nucleotides in         length may be G or C for one or more nucleotides in the         nucleotide sequence and A or T for one more nucleotides in the         nucleotide sequence.         The a concentration of a second oligonucleotide may be greater         than a sum of the concentrations of each species of first         oligonucleotide. The first region may comprise between 3 and 25         nucleotides. n may be between 3 and 60, 3 and 18, or 3 and 10,         and not greater than the number of nucleotides in the first         region. The first region may further comprise at least one         nucleotide in addition to the nucleotide sequence of n         nucleotides in length. The second region may comprise between 8         and 200 nucleotides. The barcode sequence of each species of         precursor molecule may be selected based on the method as set         forth above. The at least one species of precursor molecule may         be chemically synthesized or produced enzymatically. The enzyme         used to produce the at least one species of precursor molecule         may be a ligase or a polymerase.

In an additional embodiment, there is provided a method for purifying multiple target nucleic acid molecules from a sample comprising a plurality of precursor molecules, wherein the method comprises the steps of:

-   -   providing a plurality of nucleic acid probes, wherein each probe         has a sequence complementary to a region of one of the precursor         molecules and a first moiety sufficient to allow isolation of         the probe;     -   adding the plurality of nucleic acid probes to a sample         comprising the plurality of precursor molecules under conditions         sufficient to promote hybridization of each nucleic acid probe         to the region of the precursor molecule complimentary to the         sequence thereby forming a plurality of probe-precursor         complexes, wherein each precursor molecule comprises a different         target nucleic acid molecule, and wherein the region of each         precursor molecule does not comprise the target nucleic acid         molecule; and     -   isolating the plurality of probe-precursor complexes via         interaction with the first separating the target nucleic acid         molecules from the plurality of probe-precursor.

Another embodiment provides for a method for producing a plurality of distinct target oligonucleotides each having a specified sequence, the method comprising:

-   -   (1) synthesizing a precursor oligonucleotide for each distinct         target oligonucleotide, wherein the precursor comprises a third         sequence, a fourth sequence, and a fifth sequence, wherein the         third sequence is identical for all precursors, the fourth         sequence comprises a barcode and is distinct for all precursors,         and a fifth sequence corresponds to the target sequence,     -   (2) synthesizing a capture probe library of distinct         oligonucleotides comprising a first sequence and a second         sequence, wherein the first sequence comprises degenerate         randomer nucleotides and wherein at least one first sequence is         complementary to each fourth sequence, and the second sequence         is complementary to the third sequence,     -   (3) mixing the precursors and the capture probe library in an         aqueous hybridization buffer,     -   (4) removing precursor molecules not bound to the capture         probes,     -   (5) enzymatically or chemically cleaving the fifth sequence from         the remainder of the precursor molecules, and     -   (6) removing the capture probe library and the remainder of the         precursor molecules.         The first sequence may comprise an S degenerate nucleotide at         certain positions and/or a W degenerate nucleotide at certain         positions, but may not comprise an N degenerate nucleotide at         any position, such that any degenerate variant of the first         sequence is complementary to one or more fourth sequences,         wherein S is a strong base, W is a weak base, and N is any base.         The capture probes may be functionalized with a moiety         permitting for rapid binding to a ligand, such as a moiety         selected from a biotin, a thiol, an azide, or an alkyne. In step         (4), eliminating precursor molecules not bound to capture probes         may comprise adding particles that specifically bind the capture         probe, followed by removal of supernatant solution. The         particles may be selected from streptavidin-coated magnetic         beads or streptavidin-coated agarose beads. The precursors may         further comprise a deoxyuracil nucleotide or an RNA nucleotide,         and cleavage of the fifth sequence comprises introduction of a         uracil DNA glycosylase or an RNAse enzyme. The precursors may         further comprise a photolabile or heat-labile moiety, and the         cleaving of the fifth sequence comprises exposure of the         solution to light of the appropriate wavelength or heating to         the appropriate temperature. The fourth sequence may further         comprise the “S” degenerate nucleotide at certain positions         and/or the “W” degenerate nucleotide at certain positions, but         does not comprise the “N” degenerate nucleotide at any position.         The length of the first sequence may be between 5 and 50         nucleotides, and wherein the number of degenerate nucleotides is         between 1 and 30, between 1 and 20, between 1 and 10, between 2         and 8, between 2 and 6, or between 3 and 5. The length of the         second sequence may be between 5 and 50 nucleotides, and/or         wherein the length of each target oligonucleotide is between 5         and 500 nucleotides.

In an additional embodiment, there is provided an oligonucleotide capture probe library comprising a first sequence and a second sequence, wherein the first sequence comprises degenerate randomer nucleotides comprising an “S” degenerate nucleotide at one or more positions and/or a “W” degenerate nucleotide at one or more positions, but does not comprise an “N” degenerate nucleotide at any position, and wherein the length of the first sequence is between 5 and 50 nucleotides, the number of degenerate nucleotides is between 1 and 30, and the length of the second sequence is between 5 and 50 nucleotides. The second sequence may comprise an “S” degenerate nucleotide at certain positions and/or a “W” degenerate nucleotide at certain positions, but does not comprise a “N” degenerate nucleotide at any position. The oligonucleotide capture probe library may be functionalized with a chemical moiety for rapid binding, selected from a biotin, a thiol, an azide, or an alkyne. The one or more of the oligonucleotide capture probes may further comprise a deoxyuracil nucleotide or an RNA nucleotide. The one or more of the oligonucleotide capture probes may further comprise a photolabile or heat-labile moiety. The length of the first sequence may be between 5 and 50 nucleotides, and wherein the number of degenerate nucleotides may be between 1 and 30. The length of the second sequence may be between 5 and 50 nucleotides. The library may have at least 8, at least 32, or at least 256 members. The library may have between 8 and 32 members, between 8 and 256 members, between 32 and 256 members, between 8 and 1024 members, between 32 and 1024 members, or between 256 and 1024 members. The library may be found on one or more substrates.

In still an additional embodiment, there is provided an aqueous solution comprising an oligonucleotide capture probe library, a plurality of precursor oligonucleotides and a set of precursor oligonucleotides, wherein:

-   -   the capture probe library comprises a first sequence and a         second sequence, wherein     -   the first sequence comprises degenerate randomer nucleotides         comprising an “S” degenerate nucleotide at certain positions         and/or an “W” degenerate nucleotide at certain positions, but         does not comprise an “N” degenerate nucleotide at any position,         and wherein the length of the first sequence is between 5 and 50         nucleotides, the number of degenerate nucleotides is between 1         and 30, and the length of the second sequence is between 5 and         50 nucleotides,     -   each of the plurality of precursor oligonucleotides comprises a         third sequence, a fourth sequence, and a fifth sequence, wherein         the third sequence is identical for all precursors, the fourth         sequence comprises a barcode and is distinct for all precursors,         the second sequence is complementary to the third sequence, and         at least one instance of a first sequence is complementary to         each fourth sequence.         The second sequence of the oligonucleotide capture probe library         may comprise an “S” degenerate nucleotide at certain positions         and/or a “W” degenerate nucleotide at certain positions, but may         not comprise a “N” degenerate nucleotide at any position. The         oligonucleotide capture probe library may be functionalized with         a chemical moiety for rapid binding, selected from a biotin, a         thiol, an azide, or an alkyne. The one or more of the         oligonucleotide capture probes further may comprise a         deoxyuracil nucleotide or an RNA nucleotide. The one or more of         the oligonucleotide capture probes may further comprise a         photolabile or heat-labile moiety. The length of the first         sequence of the oligonucleotide capture probe library may be         between 5 and 50 nucleotides, and the number of degenerate         nucleotides may be between 1 and 30. The length of the second         sequence of the oligonucleotide capture probe library may be         between 5 and 50 nucleotides. The oligonucleotide capture probe         library may have at least 8, at least 32, or at least 256         members. The oligonucleotide capture probe library may have         between 8 and 32 members, between 8 and 256 members, between 32         and 256 members, between 8 and 1024 members, between 32 and 1024         members, or between 256 and 1024 members. The oligonucleotide         capture probe library may be found on one or more substrates.         The precursors may further comprise a deoxyuracil nucleotide or         an RNA nucleotide, and cleavage of the fifth sequence comprises         introduction of a uracil DNA glycosylase or an RNAse enzyme.

The use of the word “a” or “an” when used in conjunction with the term “comprising” in the claims and/or the specification may mean “one,” but it is also consistent with the meaning of “one or more,” “at least one,” and “one or more than one.” The word “about” means plus or minus 5% of the stated number.

It is contemplated that any method or composition described herein can be implemented with respect to any other method or composition described herein. Other objects, features and advantages of the present disclosure will become apparent from the following detailed description. It should be understood, however, that the detailed description and the specific examples, while indicating specific embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the disclosure will become apparent to those skilled in the art from this detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

The following drawings form part of the present specification and are included to further demonstrate certain aspects of the present disclosure. The disclosure may be better understood by reference to one or more of these drawings in combination with the detailed description of specific embodiments presented herein.

FIG. 1: Schematic overview of one embodiment of Stoichiometric Nucleic Acid Purification (SNAP). A sample mixture containing two precursors of oligonucleotide targets also contains a number of truncation synthesis products that are not desired. Through the course of the method described in this disclosure, full length target oligonucleotides are produced in roughly equal stoichiometry.

FIG. 2: Schematic of a capture probe library and corresponding set of target sequences. Within the targets libraries, region 3 is conserved while regions 4 and 5 are different for each target sequence. Similarly, within a library of capture probes region 2 is conserved, while region 1 contains variable positions with two or more nucleosides being possibly present at each variable position. (SEQ ID NOS: 404-409)

FIG. 3: Multiplexed oligonucleotide purification workflow. The process consists of 6 sequential steps. In step 3, solid phase consists of functionalized magnetic beads that enable the phase separation in steps 4 and 6. Depending on whether the user desires target sequences with or without the universal region 3 and barcode region 4, in step 5 either heat/NaOH denaturation or restriction enzyme cleavage can be used after the purification to separate the final products from the library and magnetic beads.

FIG. 4: Removal of regions 3 and 4 from target sequences using an enzyme. The desired region 5 can be enzymatically cleaved from the 5′ regions 3 and 4 used for purification, for applications where such sequences are undesirable. Site-specific cleavage can be implemented through use of (a) uracil DNA glycosylase alone or in a formulation containing DNA glycosylase-lyase Endonuclease VIII—commercially known as USER, (b) RNAse, (c) FokI endonuclease, or other methods known to one of ordinary skill in the art. The sequence or chemical composition of regions 3 and 4 may be adapted to accommodate the anticipated enzymatic cleavage process. (SEQ ID NOS: 410-417 and 251)

FIG. 5: Use of multiple barcodes for the same target sequence increases its concentration in the final purified mixture. Degenerate nucleotides (i.e., S=G or C and W=A or T) within the barcode region 4 facilitates the achievement of arbitrary desired stoichiometric ratios of targets by avoiding individual synthesis of a number numbers of precursor oligonucleotides. (SEQ ID NOS: 418-421)

FIG. 6: Proof of concept results using fluorescent labelled oligonucleotides, assayed through fluorescent polyacrylamide gel electrophoresis. 160 pmol of a capture probe library biotinylated in 3′ end, comprising 64 different region 1 sequences, is incubated with 64 synthetic unpurified precursor oligonucleotides each at 10 pmol. Each precursor oligonucleotide has a uniquely assigned region 4, complementary to one and only one instance of region 1 on the capture probe species. Lane 1 shows the length distribution of Precursor 1, and Lane 2 shows the length distribution of Precursor 1 after undergoing SNAP, but without cleavage of regions 3 and 4. Lane 3 shows the SNAP product after cleavage of regions 3 and 4. Lane 4 shows the length distribution of the corresponding commercially provided PAGE-purified oligo as comparison. Lanes 5-10 show that, regardless of initial stoichiometric ratio of the 3 Precursors, the final stoichiometry of the SNAP products are close to 1:1:1. The SNAP protocol used for this series of experiments is as follows: The capture probe library and Precursors are allowed to hybridize for 2 hr at 60° C. in 0.5M NaCl pH 7.5. Subsequently, 3 mg of streptavidin coated magnetic beads (pre-washed with the same incubation buffer) are added to the oligonucleotide mixture to a final volume of 100 μL, and incubated for 30 min at 60° C., with the sample being rocked by a shaker. The supernatant is then discarded and the magnetic beads are washed twice in the incubation buffer and one time in the buffer to be used for the subsequent enzymatic cleavage. For lane 2, the full-length precursors are eluted using 50% v/v formamide at 95° C. for 5 to 15 min For lane 3, the beads were re-suspended in USER buffer, and 2 enzymatic units of USER enzyme mix were added to achieve a final volume of 25 μL; this mix was then incubated for 1 hour at 37° C. Finally supernatant containing the desired purified target is extracted.

FIGS. 7A-B. Characterization of purity and stoichiometry for multiplexed SNAP. 64 separate Precursors (10 pmol each) were simultaneously purified via SNAP. (FIG. 7A) Next Generation Sequencing was used to characterize the purity of the 64 oligos, where the purity is operationally defined as the number of perfectly aligned reads divided by the number of reads aligned by Bowtie 2. The purity of the SNAP products are significantly higher than that of individually PAGE purified oligonucleotides (median 79% vs. 61%). (FIG. 7B) Digital droplet PCR was used to evaluate the stoichiometries of the 64 SNAP product oligonucleotides.

FIG. 8: Characterization of purity for 256-plex SNAP purified (2.5 pmol of each Precursor).

FIGS. 9A-D: Four possible variations in design of the capture probe libraries.

FIG. 10: Experimental results on double-stranded capture probe article shown in FIG. 9B. SNAP was performed using 640 pmol of capture probe biotinylated in 5′end, 1280 pmol of protector strand, and 40 pmol of one unpurified Precursor. Note that, unlike in FIG. 6, only a single Precursor species is introduced, so that the Capture Probes are NOT saturated by Precursors. SNAP protocol is otherwise similar to FIG. 6 caption. Lane 1 corresponds to the unpurified Precursor, Lane 2 corresponds to the PAGE-purified Target oligo, Lane 3 corresponds to the SNAP product without cleavage of regions 3 and 4, and Lane 4 corresponds to the final SNAP product. Lanes 5-10 show that, regardless of initial stoichiometric ratio of the 3 Precursors, the final stoichiometry of the SNAP products are close to 1:1:1.

FIG. 11: Purification of RNA transcripts produced from a synthetic DNA template that comprises regions 3 and 4.

FIG. 12 Cumulative distribution of ΔG°_(rxn) for two different randomer sequences, each producing 64 instances. Using an SWSWSW library (flanked by CA in 5′ end and C in 3′ end) produces a tight thermodynamics range of 0.8 kcal/mol window. In contrast, using a TGANNN library results in a spread of more than 4 kcal/mol.

FIGS. 13A-C: Algorithm for the design of probe libraries and assignment of barcodes (region 4).

FIG. 14: Workflow for the characterization of purity of oligonucleotides libraries through NGS. The oligonucleotides share a universal region at the 3′ end, which is used to align and enzymatically extend one short sequence used as primers. Upon the phosphorylation of the 5′ end of the newly formed double stranded library, adaptors containing sequencing primers are enzymatically attached. Finally, the resulting library is amplified for 3 PCR cycles, to introduce the P7 and P5 sequences used for the cluster generation and the consequent sequencing with an Illumina instrument.

FIG. 15: Workflow for the characterization of stoichiometries within oligonucleotides libraries through digital droplet PCR (ddPCR). The oligonucleotides of the library share a common region at 3′ end for the priming with a reverse primer, which is added as well as the master mix contain the enzyme and the EvaGreen dye for ddPCR reaction. The reaction mixture is distributed in 64 equal aliquots, each of which receives one forward primer specific for one oligonucleotide sequence within the library. Subsequently oil is added to every sample, which undergoes to the emulsion process. Finally, upon the PCR reaction, the fluorescent reader is used to determine the ratio between the droplets-containing amplification product and those that are empty, ratio that give a statistical quantification of the template molecule that have been amplified.

DETAILED DESCRIPTION

The goal of this disclosure is outlined shown in FIG. 1: different precursor oligonucleotides are synthesized with various yields and purities, and pooled together to form an input oligonucleotide pool. Through a process of SNAP purification, an output pool of target oligonucleotides is produced with no truncation products, and exhibiting a desired stoichiometric ratio (1:1 in FIG. 1).

In certain aspects of the present disclosure, toehold probes with a randomer toehold sequence are used to capture artificially designed 5′ sequence of the target oligonucleotides. Because the probes are toehold probes which are selective to single nucleotide variations, even truncated synthesis products one nucleotide shorter than the full-length product will not be efficiently captures.

I. PRECURSOR OLIGONUCLEOTIDES

A full-length precursor oligonucleotide comprises three regions, labeled as 3, 4, and 5 in FIG. 2. Region 3 is also referred to as the validation region, and the sequence of region 3 is conserved across all precursor species. Region 4 is also referred to as the barcode, and the sequence of region 5 is unique to each precursor species. Region 5 is referred to as the target sequence, and is the only portion of the oligonucleotide that should remain after the purification process. Across different precursor species, some region 8's may be unique, while others may be redundant. In some embodiments, the nucleotide to the 5′ of region 5 is a modified nucleotide (e.g., a deoxyuracil nucleotide, or an RNA nucleotide) that can be site-specifically cleaved.

Because DNA synthesis (both chemical and enzymatic) is imperfect, there will exist truncation products in which precursors lack one or more nucleotides at either the 5′ end (chemical synthesis) or the 3′ end (enzymatic synthesis).

II. CAPTURE PROBE LIBRARY

FIG. 2 shows one preferred embodiment of the capture probe library used to perform SNAP purification for chemically synthesized oligonucleotides with truncations at the 5′ end. In this embodiment, the library comprises two types of oligonucleotides: the probe oligonucleotides (comprising regions 1 and 2). In certain aspects, the probe oligonucleotides are functionalized at the 3′ end with a biotin, in order to allow capture by streptavidin-functionalized magnetic beads.

The sequence of region 1 is designed and synthesized as a randomer library, in which one or several positions contain a mixture of multiple nucleotides. The complement of every precursor species' barcode (region 4) should exist as an instance of the region 1 randomer library.

The sequence of region 2 is designed to be complementary to the sequence of region 3 on precursors.

III. SEQUENCE DESIGN OF RANDOMER REGION 1

The variable positions and allowable nucleotides at each variable position should be designed such that the standard free energy of hybridization of each instance region 1 to its perfect complement are similar. In some embodiments, the sequence of region 1 comprises S (strong, mixture of G and C) and W (weak, mixture of A and T) degenerate nucleotides.

As one example of an undesirable sequence construction, if region 4 is designed as a 7nt NNNNNNN region, then both GCGCGCG and TATATAT members will be present. The ΔGo of these two members pairing with their complements at 37° C. in 1M Na+ are −13.23 kcal/mol and −4.38 kcal/mol, respectively, according to SantaLucia Jr, J., & Hicks, D. (2004). The thermodynamics of DNA structural motifs. Annu. Rev. Biophys. Biomol. Struct., 33, 415-440. This 9 kcal/mol difference can result in the GCGCGCG member capturing its target with >99.9% yield while the TATATAT member capturing its target with <0.1% yield; such a large difference in capture yield would be clearly undesirable for achieving uniform or ratiometric product quantity/concentration distributions.

For this reason, the nucleosides present at variable positions are designed to be either S or W. That is to say, some variable positions contain either an A or T nucleoside but not G or C, while other variable positions contains G or C but not A or T. Based on published literature parameters, there is only a maximum difference of 0.17 kcal/mol per base stack for SW and for WS stacks, at 37° C. in 1M Na+.

IV. SEQUENCE-SPECIFIC CAPTURE

In those instances where the number of different probes is equal the number of the target sequences, and the total concentration of probes is lower than the total concentration of target, any instance of region 1 only hybridizes to its perfectly complement in region 4, as any other non-specific hybridization will be outcompeted.

Consequently, if the probe oligonucleotide library is synthesized such that all instance sequences are equally represented, and if the concentration of all precursors exceed that of their corresponding probe sequences, then the amount of precursor captured should be roughly stoichiometric, regardless of the initial stoichiometric ratio between the precursors. As a numerical example, if the sequence of region 1 is “GWSWSWST”, then there are 2⁶=64 instance sequences. Assuming a total probe concentration of 6.4 μM, each sequence instance would have a concentration of approximately 100 nM. For an initial precursor pool in which the concentrations of each precursor species ranges between 200 nM and 10 μM, the amount of each precursor bound to the probe will be limited by probe instance sequence concentration to a maximum of 100 nM, except insofar as off-target hybridization between precursors and their non-cognate probe instance sequences hybridize.

As another mathematical example, a probe library with 12 variable position, and 2 possible nucleotides at each position is comprised of 2¹²=4096 members. Assuming a total amount of 4 nanomoles (nmol) of the library, each member is expected to be present at quantity of roughly 1 pmol. This library is suitable for purification of up to 4096 targets, each with quantity of >10 pmol. Array oligonucleotide synthesis providers often produce panels of oligonucleotides at either the 10 pmol or 100 pmol scale.

V. SEPARATION OF PRECURSORS BOUNDED TO PROBES

The precursor oligonucleotides bound to the probe oligonucleotides are separated from other precursors using the probes as marker for recovery, through the use of a solid support or enzymatic degradation of unbound molecules, for example, using an exonuclease (e.g., 5′-3′) for single-strand digestion. In a particular embodiment, the probe oligonucleotides are biotin-functionalized at the 3′ end, and streptavidin-functionalized magnetic beads are added to solution after the hybridization reaction between the precursors, protectors, and probes. Washing the magnetic bead suspension in the vicinity of a magnetic removes unbound molecules.

VI. REMOVAL OF REGIONS 3 AND 4 FROM TARGETS

For many applications with purified pools of target oligonucleotides, the sequences of regions 3 and 4 would be an undesirable artifact. The sequence or composition of these regions may be designed to facilitate enzymatic removal of these regions from the desired target sequence after surface-based purification. FIG. 4 shows several strategies for enzymatically cleaving the captured target sequences after region 4 to remove all artifact sequences, or after region 3 to remove the purification sequence but not the barcode.

VII. SNAP PURIFICATION WORKFLOW

FIG. 3 shows one embodiment of the overall SNAP purification workflow. Hybridization durations, buffers, and temperatures vary depending on the concentration of the probe and precursor oligonucleotides, and reasonable parameter values are known to those ordinary in the art of nucleic acid hybridization probes. The capture of biotin-functionalized probes by magnetic beads and subsequent wash protocols are typically provided by suppliers of biotin-functionalized magnetic beads (e.g., Thermo Fisher Dynabeads, New England Biolabs streptavidin magnetic beads). The USER enzyme (e.g., from New England Biolabs) can be used to site-specifically cleave precursor oligonucleotides at dU positions.

VIII. RATIOMETRIC CONCENTRATIONS OF PURIFIED TARGETS

Through the use of multiple barcodes (region 4) for the same target sequence (region 5), it is possible to adjust the stoichiometric ratios of different target sequences after SNAP purification. FIG. 5 shows an example in which 3 different target sequences are sought to be purified in a 1:2:6 ratio.

The number of available barcodes based on variable positions determines the range of available stoichiometric ratios and number of sequences possible. For example, a probe library with 12 variable positions and 2 possible nucleotides at each position contains 2¹²=4096 sequence instances. The sum of all integer stoichiometry ratios among different target sequences must sum to 4096 (or less). For example, it is possible to purify a library of 2097 target sequences, in which 2096 target sequences are at equal stoichiometry to one another, and the last target sequence is present at 1000× excess.

Importantly, degenerate randomer sequences can also be incorporated in region 4 of the precursor sequences, in order to reduce the cost of precursor synthesis. For example, in FIG. 5, Target 2 occupies two sequence instances of the barcode through the use of a degenerate W in region 7.

In some instances, to yield uniform concentrations of target oligonucleotides in the final pool, the capture probe library should be at a significantly lower concentration than the input target oligonucleotide sample. For example, the full-length product of Target 1 is initially at 5 μM and the full-length product of Target 2 is initially at 8 μM, each member of the capture probe library should be kept below 5 μM, such as 1 μM. In such an instance, the purification yield may be lower than for HPLC and PAGE methods for single targets but will provide a uniform final concentration of target molecules. In instances where a uniform final target concentration is not needed, the yield will not be reduced in such a way.

IX. BARCODE ASSIGNMENT BASED ON TARGET SEQUENCE

To simultaneously achieve high sequence specificity and high hybridization yield, the standard free energies of hybridization (ΔG°Hyb) between the different precursor and their respective matched probe sequence instances must be similar. Naive design of the validation region sequence (region 3) and assignment of barcodes (region 4) may result in precursor oligonucleotides with significant secondary structure between region 5 and regions 3 and 4, resulting in ΔG°Hyb significantly more positive than expected, in turn leading to lower capture yields. Consequently, it is suggested that the sequences of regions 3 and 4 be rationally designed given desired target sequences, so that similar secondary structure is observed for all precursor sequences.

X. EXAMPLES

The following examples are included to demonstrate preferred embodiments. It should be appreciated by those of skill in the art that the techniques disclosed in the examples that follow represent techniques discovered by the inventors to function well in the practice of embodiments, and thus can be considered to constitute preferred modes for its practice. However, those of skill in the art should, in light of the present disclosure, appreciate that many changes can be made in the specific embodiments which are disclosed and still obtain a like or similar result without departing from the spirit and scope of the disclosure.

Example 1—Stoichiometric SNAP Purification

FIG. 6 shows data demonstrating proof-of-concept of the SNAP purification technique. Denaturing polyacrylamide gel electrophoresis is used to visualize and quantitate the purity and concentration of different oligonucleotide species. Lane 1 shows a chemically synthesized precursor oligonucleotide, and lane 4 shows the corresponding chemically synthesized target oligonucleotide. Both the precursor and the target oligonucleotides were synthesized with a 3′ FAM fluorophore functionalization to allow easy visualization. Lanes 2 shows the captured precursor molecules before USER enzyme treatment to remove regions 3 and 4, and Lane 3 shows the final purified product after USER enzyme treatment. The relative lack of truncation bands in Lanes 2 and 3 indicate that truncation products have been removed.

Lane 5 shows a mixture of 3 precursor oligonucleotides of different lengths (100nt, 90nt, and 80nt), prepared at a nominal stoichiometric ratio of 1:1:1. Lane 6 shows the output of the SNAP purification protocol. The stoichiometric ratio of the purified target oligonucleotides was quantitated to be 1.2:1:1.5. Lane 7 and 8 show a similar set of experiments, except the 3 precursor oligonucleotides were nominally prepared at 1:5:25 and the SNAP-purified products were observed to be at 1.2:1:1.7, and is closer to the designed 1:1:1 stoichiometric than the precursors. Lane 9 and 10 show a similar set of experiments, except the 3 precursor oligonucleotides were nominally prepared at 5:25:1 and the SNAP-purified products were observed to be at 1.2:1:0.5.

FIGS. 7A-B show data demonstrating purity and stoichiometry attainable by means of SNAP purification as measured by Next Generation Sequence and digital droplet PCR. FIG. 7A shows that the median of reads perfectly matching the desired sequence is about the 80%, in case of SNAP purification, which is greater that the median from PAGE purification which is about 60% and the one from unpurified oligos, which is about 55%. FIG. 7B shows the concentration of the individual sequences as measured through digital droplet PCR, using target specific primers. After the SNAP purification the concentration of the oligo is within a factor of two for the 95% of the sequences of the pool.

FIG. 11 shows data demonstrating purity for a 256-plex, as measured by NGS. Also in this case the fraction of perfect reads for SNAP purified oligo is close the 80%.

Example 2—Purification of Enzymatically-Produced Precursors

FIG. 10 shows an example embodiment of purifying enzymatically produced precursors, in this case a transcribed RNA species. Chemical synthesis of RNA oligonucleotides is significantly (8-fold) more expensive than DNA synthesis, and limited to shorter lengths (typically <50nt). In vitro transcribed RNA using RNA polymerase and a corresponding DNA template sequence can produce economically produce large quantity of desired RNA target sequences that is also significantly longer than chemically synthesized RNA, but requires labor-intensive Polyacrylamide Gel electrophoresis (PAGE) purification. The present SNAP purification methods can significantly reduce the labor needed to produce RNA molecules, especially in highly multiplexed settings.

Because enzymatically produced precursors disproportionately exhibit truncations and errors at the 3′ end rather than the 5′ end, the DNA template sequence is designed so that the validation and barcode regions (3 and 4, respectively) will be positioned at the 3′ end of the transcript. The stoichiometric capture of full-length precursor RNA transcripts occurs similarly to that of DNA oligonucleotides described previously. An RNAse H enzyme may be used to remove regions 6 and 7 from the precursor to leave only the desired target RNA sequence, because RNAse H will selectively cleave RNA at regions where it is hybridized to DNA.

Example 3—Probe Design Variations

FIGS. 9A-D show a few possible variations in design of the probe and protector sequences. The relative ordering of the regions may be altered, as long as the complementarity relationship between the regions are preserved (e.g., region 2 is complementary to region 3).

FIG. 9B In those instances when the number capture probes is higher than the number or target sequences, as well as in those case where multiple validation regions (region 2) are used simultaneously, the purpose of the protector oligonucleotide and of regions 7 and 8, is to ensure sequence-specific hybridization of each precursor to its matched probe oligonucleotide. Zhang, D. Y., Chen, S. X., & Yin, P. (2012). Optimizing the specificity of nucleic acid hybridization. Nature chemistry, 4(3), 208-214. and Wu, L. R., Wang, J. S., Fang, J. Z., Evans, E. R., Pinto, A., Pekker, I., & Zhang, D. Y. (2015). Continuously tunable nucleic acid hybridization probes. Nature methods, 12(12), 1191-1196. shows that the competitive hybridization between precursors and the protectors is specific to even single-nucleotide changes in sequence when the sequences of the probe and protector are designed appropriately.

This specificity is useful for 2 purposes: First, it limits the off-target hybridization of precursors to non-cognate probe sequence instances that are not perfectly complementary. Second, it prevents the hybridization of imperfectly synthesized precursors that lack any nucleotide in regions 3 or 4.

Unless explicitly stated otherwise, “complementary” in this document refers to “partially or fully complementary”. Two sequences are defined to be “partially complementary” when over 80% of the aligned nucleotides of one sequence is complementary to corresponding nucleotides of the other sequence.

Tables 1-4, below, shows a hypothetical set of sequences for the precursors, capture probe and protector that could be used in methods of the present disclosure. In the sequence of the capture probe, S or W indicates that all variants are included in the capture probe library. For example, both A and T would be present in the mixture of capture probes at each W as part of the randomer library of capture probes.

TABLE 1 List of 64 precursor for the 64plex described in FIGS. 7A-B Name Region 3 Region 4 Region 5 NGSPlex64_ TAGGTGC TGTGAC GCCCGTCGGCATGTATTAGCTCTAGAATTACCACAGTGCA 1 GGTCGCA TCACTG ACCTTTCGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 3 1 NO: 2 NGSPlex64_ TAGGTGC TGTCTG GGGGCCGGAGAGGGGCTGACCGGGTTGGTTTTGATGCG 2 GGTCGCA TGTCTG GTGCTCGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 5 1 NO: 4 NGSPlex64_ TAGGTGC TGTCAC CCCTGATTCCCCGTCACCCGTGGTCACCATGGTAGTGGC 3 GGTCGCA ACTCTG CATAGCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 7 1 NO: 6 NGSPlex64_ TAGGTGC TGTGAC TTTTTCGTCACTACCTCCCCGGGTCGGGAGTGGGTGAATT 4 GGTCGCA ACTCTG ATGCTGAACGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 9 1 NO: 8 NGSPlex64_ TAGGTGC TGTGAG GCCCGCCCGCTCCCAAGATCCAACTACGAGCTTTTAGGT 5 GGTCGCA AGACTG CAGTGGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 11 1 NO: 10 NGSPlex64_ TAGGTGC TGTGTC GGCCGTCCCTCTTAATCATGGCCTCAGTTCCGAAACCTAC 6 GGTCGCA TGTCTG ACATTATCTGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 13 1 NO: 12 NGSPlex64_ TAGGTGC TGTGAG GGTATCTGATCGTCTTCGAACCTCCGACTTTCGTTCTGGA 7 GGTCGCA TCACTG CATGCCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 15 1 NO: 14 NGSPlex64_ TAGGTGC TGTCTC TGGTGGTGCCCTTCCGTCAATTCCTTTAAGTTTCATGCTTC 8 GGTCGCA AGACTG TACTCCTAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 17 1 NO: 16 NGSPlex64_ TAGGTGC TGTCAC CCTGTCCGTGTCCGGGCCGGGTGAGGTTTCCCGTGCACT 9 GGTCGCA TCACTG AGGGCTGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 19 1 NO: 18 NGSPlex64_ TAGGTGC TGTGAC GTAACTAGTTAGCATGCCAGAGTCTCGTTCGTTATCGGAT 10 GGTCGCA TGTCTG GGCCTAGTATAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 21 1 NO: 20 NGSPlex64_ TAGGTGC TGTCAC GCCCCGGACATCTAAGGGCATCACAGACCTGTTATTCCTT 11 GGTCGCA TCTCTG GTTGAAGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 23 1 NO: 22 NGSPlex64_ TAGGTGC TGTCTC GGTAGTAGCGACGGGCGGTGTGTACAAAGGGCAGGTGA 12 GGTCGCA AGTCTG GTATTTGATTCAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO:25 1 NO: 24 NGSPlex64_ TAGGTGC TGTCTC GGCGCTGGGCTCTTCCCTGTTCACTCGCCGTTACTATGTT 13 GGTCGCA TGACTG CGGCCTTTTTAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 27 1 NO: 26 NGSPlex64_ TAGGTGC TGTGTG TACCACCCGCTTTGGGCTGCATTCCCAAGCAACCCCCCC 14 GGTCGCA TGACTG GAAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 29 1 NO: 28 NGSPlex64_ TAGGTGC TGTCTG CTTTCCCTTACGGTACTTGTTGACTATCGGTCTCGTAAAC 15 GGTCGCA ACACTG GGTTAGATCGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 31 1 NO: 30 NGSPlex64_ TAGGTGC TGTCTC GGCGGACTGCGCGGACCCCACCCGTTTACCTCTTAGGTA 16 GGTCGCA TCTCTG TATAACGCCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 33 1 NO: 32 NGSPlex64_ TAGGTGC TGTGAC GGTGGAAATGCGCCCGGCGGCGGCCGGTCGCCGGTACA 17 GGTCGCA TCTCTG CAGTTGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 35 1 NO: 34 NGSPlex64_ TAGGTGC TGTGTG CCTTCCCCGCCGGGCCTTCCCAGCCGTCCCGGAGCAAGA 18 GGTCGCA ACTCTG TTGTTTACAGAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 37 1 NO: 36 NGSPlex64_ TAGGTGC TGTCAG GGGATTCGGCGAGTGCTGCTGCCGGGGGGGCTGTAGGA 19 GGTCGCA TGTCTG CAACGTACAACAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 39 1 NO: 38 NGSPlex64_ TAGGTGC TGTGAC GCCGTGGGAGGGGTGGCCCGGCCCCCCCACGAGGACTA 20 GGTCGCA TGACTG CTCAAGAATTGCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 41 1 NO: 40 NGSPlex64_ TAGGTGC TGTGAG GCCGACCCCGTGCGCTCGCTCCGCCGTCCCCCTCTGCAC 21 GGTCGCA ACTCTG GCGGACAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 43 1 NO: 42 NGSPlex64_ TAGGTGC TGTGAG GTGTTAGACTCCTTGGTCCGTGTTTCAAGACGGGTGGTCA 22 GGTCGCA TGTCTG TTTAGCGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 45 1 NO: 44 NGSPlex64_ TAGGTGC TGTCTG CCAGGCATAGTTCACCATCTTTCGGGTCCTAACACGGAGC 23 GGTCGCA TCACTG CCATTACAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 47 1 NO: 46 NGSPlex64_ TAGGTGC TGTGTG GGGTGCGTCGGGTCTGCGAGAGCGCCAGCTATCCTATAA 24 GGTCGCA AGTCTG GCGCCGTCCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 49 1 NO: 48 NGSPlex64_ TAGGTGC TGTGTC GTTCGGTTCATCCCGCAGCGCCAGTTCTGCTTACCGTGC 25 GGTCGCA TCACTG CACAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 51 1 NO: 50 NGSPlex64_ TAGGTGC TGTGTG GGATTCCGACTTCCATGGCCACCGTCCTGCTGTCTGAAAA 26 GGTCGCA AGACTG AATTTCTGCAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 53 1 NO: 52 NGSPlex64_ TAGGTGC TGTCAC ACGCTCCAGCGCCATCCATTTTCAGGGCTAGTTGACGCTA 27 GGTCGCA AGACTG TGGCATCAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 55 1 NO: 54 NGSPlex64_ TAGGTGC TGTGTC GCAGCGGCCCTCCTACTCGTCGCGGCGTAGCGTCCCATT 28 GGTCGCA TCTCTG GAGCAGTTGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 57 1 NO: 56 NGSPlex64_ TAGGTGC TGTCAG ACCCTTCTCCACTTCGGCCTTCAAAGTTCTCGTTTCTAGA 29 GGTCGCA ACACTG GCCCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 59 1 NO: 58 NGSPlex64_ TAGGTGC TGTCAC ACTCTCCCCGGGGCTCCCGCCGGCTTCTCCGGGATGTGA 30 GGTCGCA ACACTG TGGGAGTACCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 61 1 NO: 60 NGSPlex64_ TAGGTGC TGTCAC GCCAGAGGCTGTTCACCTTGGAGACCTGCTGCGGACCGC 31 GGTCGCA TGTCTG TCACAAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 63 1 NO: 62 NGSPlex64_ TAGGTGC TGTCTG CCCAGCCCTTAGAGCCAATCCTTATCCCGAAGTTATCAAT 32 GGTCGCA AGACTG CAGTTGCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 65 1 NO: 64 NGSPlex64_3 TAGGTGC TGTGTC GCTCCCCCGGGGAGGGGGGAGGACGGGGAGCGGGGTT 3 GGTCGCA AGTCTG GAGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 67 1 NO: 66 NGSPlex64_ TAGGTGC TGTGAC CCCCTGC 34 GGTCGCA AGTCTG CGCCCCGACCCTTCTCCCCCCGCCGCCGTATCTAAGGTC SEQ ID NO: SEQ ID CCGTCTCGTACGGTTAAGAGCC 1 NO: 68 SEQ ID NO: 69 NGSPlex64_ TAGGTGC TGTCTG GGCGGGGGGGACCGGCCCGCGGCCCCTCCGCCGCCGT 35 GGTCGCA AGTCTG CATGTCCAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 71 1 NO: 70 NGSPlex64_ TAGGTGC TGTGAG GGATTCCCCTGGTCCGCACCAGTTCTAAGTCGGCTAGGG 36 GGTCGCA AGTCTG AAGGCAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 73 1 NO: 72 NGSPlex64_ TAGGTGC TGTCAG GGCTACCTTAAGAGAGTCATAGTTACTCCCGCCGTGGCC 37 GGTCGCA TCTCTG CTTCACCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 75 1 NO: 74 NGSPlex64_ TAGGTGC TGTGAG CACCTCTCATGTCTCTTCACCGTGCCAGACTAGAGGCGG 38 GGTCGCA TGACTG ATCCGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 77 1 NO: 76 NGSPlex64_ TAGGTGC TGTCTC GCCCCTCGGGGCTCGCCCCCCCGCCTCACCGGGTCCGG 39 GGTCGCA ACACTG AACGCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 79 1 NO: 78 NGSPlex64_ TAGGTGC TGTGTG GCCCTTCTGCTCCACGGGAGGTTTCTGTCCTCCCTAGTTT 40 GGTCGCA ACACTG GCCAGACCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 81 1 NO: 80 NGSPlex64_ TAGGTGC TGTCTC GCTTGGCCGCCACAAGCCAGTTATCCCTGTGGTAATGATC 41 GGTCGCA TGTCTG TCTCTGAGTAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 83 1 NO: 82 NGSPlex64_ TAGGTGC TGTGTG GCGGTTCCTCTCGTACTGAGCAGGATTACCATGGCGGCC 42 GGTCGCA TGTCTG AAATATAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 85 1 NO: 84 NGSPlex64_ TAGGTGC TGTCTG CCGAGGCTCCGCGGCGCTGCCGTATCGTTCCGCCTATGG 43 GGTCGCA TCTCTG AGGAGGACAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 87 1 NO: 86 NGSPlex64_ TAGGTGC TGTGAC AGGTCGTCTACGAATGGTTTAGCGCCAGGTTCCCCAGCC 44 GGTCGCA ACACTG TCAGGCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 89 1 NO: 88 NGSPlex64_ TAGGTGC TGTCAC CATCTTTCCCTTGCGGTACTATATCTATTGCGCCAGCCTC 45 GGTCGCA TGACTG CCCTCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 91 1 NO: 90 NGSPlex64_ TAGGTGC TGTCAG GACGGGTGTGCTCTTTTAGCTGTTCTTAGGTAGCTAGTAT 46 GGTCGCA AGTCTG CTCGTCCCCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 93 1 NO: 92 NGSPlex64_ TAGGTGC TGTGTC GCTTTTAGGCCTACTATGGGTGTTAAATTTTTTACTCTCTC 47 GGTCGCA ACACTG TACAAGTCGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 95 1 NO: 94 NGSPlex64_ TAGGTGC TGTCTG AGGGTGATAGATTGGTCCAATTGGGTGTGAGGAGTTCAA 48 GGTCGCA TGACTG CGTGTATTGTAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 97 1 NO: 96 NGSPlex64_ TAGGTGC TGTGTC GACTTGTTGGTTGATTGTAGATATTGGGCTGTTAATTGTCA 49 GGTCGCA ACTCTG GTTTGTTGTAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 99 1 NO: 98 NGSPlex64_ TAGGTGC TGTCTG GTAAGATTTGCCGAGTTCCTTTTACTTTTTTTAACCTTTCCT 50 GGTCGCA ACTCTG TATGCCAAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 101 1 NO: 100 NGSPlex64_ TAGGTGC TGTCAG GCTGAACCCTCGTGGAGCCATTCATACAGGTCCCTGTCC 51 GGTCGCA AGACTG ACCGGCTAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 103 1 NO: 102 NGSPlex64_ TAGGTGC TGTCAG GCTCGGAGGTTGGGTTCTGCTCCGAGGTCGCCCCACTTG 52 GGTCGCA TGACTG CATCCTTTGGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 105 1 NO: 104 NGSPlex64_ TAGGTGC TGTGTC GGATTGCGCTGTTATCCCTAGGGTAACTTGTTCCGCAGAC 53 GGTCGCA AGACTG GTTGTGCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 107 1 NO: 106 NGSPlex64_ TAGGTGC TGTCAG GCCTTATTTCTCTTGTCCTTTCGTACAGGGAGGAATTTGAA 54 GGTCGCA ACTCTG TATCTGTTTAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 109 1 NO: 108 NGSPlex64_ TAGGTGC TGTCAG TTTCCCGTGGGGGTGTGGCTAGGCTAAGCGTTTTGCATTT 55 GGTCGCA TCACTG CATAGACCTTAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 111 1 NO: 110 NGSPlex64_ TAGGTGC TGTCTC CAGGTGAGTTTTAGCTTTATTGGGGAGGGGGTGATCTACT 56 GGTCGCA ACTCTG GCATCGTTAGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 113 1 NO: 112 NGSPlex64_ TAGGTGC TGTGTC GGCTCGTAGTGTTCTGGCGAGCAGTTTTGTTGATTTGAGT 57 GGTCGCA TGACTG CTAAGGAGTAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 115 1 NO: 114 NGSPle TAGGTGC TGTGTG GTACTTGCGCTTACTTTGTAGCCTTCATCAGGGTTTGGGG x64_58 GGTCGCA TCACTG TTACCTGCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 117 1 NO: 116 NGSPle TAGGTGC TGTGAG GTGACGGGCGGTGTGTACGCGCTTCAGGGCCCTGTACAA x64_59 GGTCGCA TCTCTG TCCTGGTAAGAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 119 1 NO: 118 NGSPle TAGGTGC TGTCAC TCTTCATCGACGCACGAGCCGAGTGATCCACCGCTGTTTC x64_60 GGTCGCA AGTCTG CCTTCCAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 121 1 NO: 120 NGSPle TAGGTGC TGTGAC GATCAATGTGTCCTGCAATTCACATTAATTCTCGCAGCTA x64_61 GGTCGCA AGACTG GCGTTCACAAAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 123 1 NO: 122 NGSPle TAGGTGC TGTGTG GCTCAGACAGGCGTAGCCCCGGGAGGAACCCGGGGTCA x64_62 GGTCGCA TCTCTG CGAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 125 1 NO: 124 NGSPle TAGGTGC TGTCTC GCCTACAGCACCCGGTATTCCCAGGCGGTCTCCCAAGGA x64_63 GGTCGCA TCACTG GCATATATAACAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 127 1 NO: 126 NGSPle TAGGTGC TGTGAG GAGATCGGGCGCGTTCAGGGTGGTATGGCCGTAGAGCG x64_64 GGTCGCA ACACTG TTATCCAGTCTCGTACGGTTAAGAGCC SEQ ID NO: SEQ ID SEQ ID NO: 129 1 NO: 128 Name Region 1 Region 2 Capture CAGWSWSWS ACATGCGACCGCACCTA TTTTTTTTTT\Biotin Probe64 (SEQ ID NO: 130) plex

TABLE 2 List of 256 precursor for the 256plex of in FIG. 8 Name Region 3 Region 4 Region 5 NGSPLEx TCGCGAAAT CTCAG TCGCCGCGTAAACGACGCGGCGCGCGTGCTGCCGCACT 256_1 TCGGTTGT ACAG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 132 NGSPLEx TCGCGAAAT GACAG AGCCCGCCGCGCACGCGCCCCTGCGCCCGCGCCGCCC 256_2 TCGGTTGT ACAG CAGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 133 NGSPLEx TCGCGAAAT CTGTC CTGCTCCCGGCTGGGCCCACCGCCAAAGCAGCGGCCCC 256_3 TCGGTTGT TCAG ACAGGAGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 134 NGSPLEx TCGCGAAAT GTCAC CTCCTCCGGCCCCGCGCGCCCACTCCGCGCCCGGCCTG 256_4 TCGGTTGT ACAG GCCGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 135 NGSPLEx TCGCGAAAT CAGAC GCCGCCGCCGCCGCCGCCGCCGCCGCCCCGCTGCCTT 256_5 TCGGTTGT TCAG CTCAGCCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 136 NGSPLEx TCGCGAAAT CAGTG GCGGGTGGGCGGCCCGCGTTCCTTAGCCGCGGCTCCG 256_6 TCGGTTGT TGAG CGGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 137 NGSPLEx TCGCGAAAT GAGTC CCATTCCTGCCAGACCCCCGGCTATCCCGGTGGCCAGG 256_7 TCGGTTGT TCAG CTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 138 NGSPLEx TCGCGAAAT GACTC GGCCTCGCGTGCCTGGACAGCCCCGCGGGCCAGCAAG 256_8 TCGGTTGT TCAG CCTATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 139 NGSPLEx TCGCGAAAT CTCTC CCATCTCAGGGTGAGGGGCTTCGGCAGCCCCTCATGCT 256_9 TCGGTTGT TCAG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 140 NGSPLEx TCGCGAAAT CACAC GCGACCAAAGGCCGGCGCACGGCCTGGCCGCTCAGCG 256_10 TCGGTTGT AGTG ACTCCCGGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 141 NGSPLEx TCGCGAAAT GTGTG CGCGGCCTCAAAAGGCCTCCTAGGCCGCGGCGGGCAAA 256_11 TCGGTTGT TCAG GCACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 142 NGSPLEx TCGCGAAAT GTGTC TACGCTCTCGCGCACCAGGTACGCCTGGTGTTTCTTTGT 256_12 TCGGTTGT AGAG GGTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 143 NGSPLEx TCGCGAAAT GAGAG CTCTGCCCAATCCCGGCTCCGGGCGACCCGGGCCCCTG 256_13 TCGGTTGT TGTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 144 NGSPLEx TCGCGAAAT CACTC TCTTGTAGGAGGCCCATTCCTCCCACCACGGGGCCACC 256_14 TCGGTTGT TGAG CACCCCGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 145 NGSPLEx TCGCGAAAT CTGAC CAGCCCCCAAACCCGACTGGTCGAAGGGGGACATCAAG 256_15 TCGGTTGT TGTG TCCCCCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 146 NGSPLEx TCGCGAAAT GTCTC CGCAGCCGACGCCGGCGCGAGAGCAGGGGCGGGGCCG 256_16 TCGGTTGT ACTG GCGCGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 147 NGSPLEx TCGCGAAAT CAGTC GGCCCGCTCGGCAGGCCCCAACTGGCCCTCCCCCTTGG 256_17 TCGGTTGT AGAG CGGCGATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 148 NGSPLEx TCGCGAAAT GAGTG CGGGCCGAATGCCAGCCCGCCGAGCTCAGGGCAGCGG 256_18 TCGGTTGT TCAG GGAGCTGGTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 149 NGSPLEx TCGCGAAAT CACAG ACCTCCGCTGCGTCTCTCCGCGCCGCCGCCGCTGCTCG 256_19 TCGGTTGT TGAG CCGTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 150 NGSPLEx TCGCGAAAT CTCAC CGGCCCAGGTCTCGGTCAGGGCCAGGGCCGCCGAGAG 256_20 TCGGTTGT AGAG CAGCAGGATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 151 NGSPLEx TCGCGAAAT GTGAG CTGCCTCACGCATCACAGCACCCCCACCCGAGCGCGGG 256_21 TCGGTTGT AGTG CGGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 152 NGSPLEx TCGCGAAAT CAGAC GGCCACGCTGCCACCAGCAGCAGGCCCATGGGGTGGCA 256_22 TCGGTTGT ACTG GGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 153 NGSPLEx TCGCGAAAT CTGTG CCAGGGGTAGCCCCCTGGATTATGGTCTGACTCAGGACT 256_23 TCGGTTGT TCAG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 154 NGSPLEx TCGCGAAAT GTGTC CGAAGTTGCCCAGGGTGGCAGTGCAGCCCCGGGCTGAG 256_24 TCGGTTGT ACTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 155 NGSPLEx TCGCGAAAT GACAC GTTACCTCCCCGCACACGGACTGTGTGGATGCGGCGGG 256_25 TCGGTTGT TCTG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 156 NGSPLEx TCGCGAAAT CAGAG AGAGCTCATGTATGGGTTAATCCGACCATGAGCTCTGTG 256_26 TCGGTTGT AGAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 157 NGSPLEx TCGCGAAAT CTGAG GGCCGGGCCACGGCCAGCATCCGGACCCGGGGCAGCG 256_27 TCGGTTGT ACAG GCGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 158 NGSPLEx TCGCGAAAT GACTC GCCATTACGGCTTCCCCGGCCAATAGACGCCCGGCTGC 256_28 TCGGTTGT ACAG CCTTACATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 159 NGSPLEx TCGCGAAAT CTCTG TTCAGCATTTCTGCTGAAATCTAGGGTGGAAATGCGTTCC 256_29 TCGGTTGT ACAG TAGTGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 160 NGSPLEx TCGCGAAAT CTCAC CTCAGCGGAAATCCGGCGATCTGGCCGGAAGTGCGGCA 256_30 TCGGTTGT TCAG CACTCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 161 NGSPLEx TCGCGAAAT GAGAC TGGCAGGAAGCTGCAGCCTTTCTCAAGAGCAGCCAGGAT 256_31 TCGGTTGT TCAG CTCCTGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 162 NGSPLEx TCGCGAAAT GAGTC GGTAGCGAGGAGAGCGGCTGAGGCTCAGTGCGCCTGC 256_32 TCGGTTGT TCTG GCGGCGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 163 NGSPLEx TCGCGAAAT GAGAG GCCATGGCAGCTTTCATGGCGTCTGGGGTTTTACCCCAC 256_33 TCGGTTGT TCAG TCATCTTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 164 NGSPLEx TCGCGAAAT CACTC TGCATCTTCAGGAGACGCTCGTAGCCCTCGCGCTTCTCC 256_34 TCGGTTGT ACAG TTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 165 NGSPLEx TCGCGAAAT CAGAG CCGTTGGCCACTTGTGGCCATTCCTACTCCCATGCCGGC 256_35 TCGGTTGT ACTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 166 NGSPLEx TCGCGAAAT CTCAG AACTGGGTCCTACGGCTTGGACTTTCCAACCCTGACAGA 256_36 TCGGTTGT TGTG CCCGCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 167 NGSPLEx TCGCGAAAT GAGAC GCCGCTGCTGCAGCAGCTGCCTTATCCACCCGGAGCTT 256_37 TCGGTTGT TGAG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 168 NGSPLEx TCGCGAAAT GTCTC ACGCGGCCTCTCCCGGCCCCTTCCGTTTAGTAGGAGCC 256_38 TCGGTTGT TGAG GCACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 169 NGSPLEx TCGCGAAAT CTCTG TGAGGGGCTTGGGCAGACCCTCATGCTGCACATGGCAG 256_39 TCGGTTGT AGAG GTGTATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 170 NGSPLEx TCGCGAAAT GTGTG CCCGGCCCAACAAACTACCTACGTCCGGGAGTCGCCAA 256_40 TCGGTTGT TGAG CCGACGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 171 NGSPLEx TCGCGAAAT GAGAC AGGCAGACTGCTGCAGGACGGGACTGGGCCGGGAACC 256_41 TCGGTTGT AGAG GGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 172 NGSPLEx TCGCGAAAT CACTG TCTAAACCGTTTATTTCTCCCCACCAGAAGGTTGGGGTG 256_42 TCGGTTGT TGAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 173 NGSPLEx TCGCGAAAT GAGTG AACACTGCCTTCTTGGCCTTTAAAGCCTTCGCTTTGGCTT 256_43 TCGGTTGT TGTG CATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 174 NGSPLEx TCGCGAAAT GTCAC CGGTAGCCGAAGGAGTTCAAAAGACCTCTAGTGCGCCCA 256_44 TCGGTTGT TCTG CCGCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 175 NGSPLEx TCGCGAAAT CTCTC GGTGACAGGGTGGCCCAGGAGCGGCCACTGAGATGAGA 256_45 TCGGTTGT TCTG CCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 176 NGSPLEx TCGCGAAAT GAGTG GATCACTCCCCAGGCGCTGAGGACGATGCCGCAGGCGG 256_46 TCGGTTGT TCTG CTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 177 NGSPLEx TCGCGAAAT GAGAG CTTAAGACCAGTCAGTGGTTGCTCCTACCCATTCAGTGG 256_47 TCGGTTGT TGAG CCTGAGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 178 NGSPLEx TCGCGAAAT GTCTG GAAGCTCCTAGAAGCTTCACAAGTTGGGGCACAACTCCT 256_48 TCGGTTGT TCTG GTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 179 NGSPLEx TCGCGAAAT CACTC TGGCGCGCGGCACTGGGAGCCGCCGGGCCGAGCCTGT 256_49 TCGGTTGT AGTG CAATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 180 NGSPLEx TCGCGAAAT GAGTC TCATAGAAAGAGAGGGAAGTTTTGGCGATCACAACAGCG 256_50 TCGGTTGT ACAG CCAAATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 181 NGSPLEx TCGCGAAAT CACTC CAAAGAATGCAAACATCATGTTTGAGCCCTGGGGATCAG 256_51 TCGGTTGT AGAG GGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 182 NGSPLEx TCGCGAAAT GTCTG GATAGCGCTCCTGTCTATTGGCTGCGCCATCGCCCGTCA 256_52 TCGGTTGT AGTG GACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 183 NGSPLEx TCGCGAAAT CTCAG CATATGCAGGTCCCCTGTTGGCCATTCCAATGGGTGGCG 256_53 TCGGTTGT TGAG GTGGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 184 NGSPLEx TCGCGAAAT CTCAG ACTCCCTGCTCCTTGGGAATACGGACCACGCAGTCTATA 256_54 TCGGTTGT TCTG ATGCCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 185 NGSPLEx TCGCGAAAT CACAC CGGGGTAACCGTGGAGGGCGACGCGCAGAGGCTGCGG 256_55 TCGGTTGT TGTG CTATTTATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 186 NGSPLEx TCGCGAAAT CAGTC GGACTGGTCCCATGAGGCAGAAGGAGCACCAGCGCCTG 256_56 TCGGTTGT TGTG CTGGGTGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 187 NGSPLEx TCGCGAAAT GTCTC CGAGAAACAGCGCCCGACACCTGGCCCTTCGCAGCTCT 256_57 TCGGTTGT TGTG CGCCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 188 NGSPLEx TCGCGAAAT CAGAG CTGCATGGCCTTCATGACATGAAGGTTGGGCACATTCTT 256_58 TCGGTTGT TGTG GTCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 189 NGSPLEx TCGCGAAAT CTGAC CCGAAACCCATGGTGTCGGCTGTATCCGAGAGCTGGGG 256_59 TCGGTTGT TGAG AGCAGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 190 NGSPLEx TCGCGAAAT GACAC TTCATGCAGATCACCTGCACCCCGCTTGTGTTCAGTGGG 256_60 TCGGTTGT TCAG GTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 191 NGSPLEx TCGCGAAAT GAGAC AGCTGCCGGGGTCCGGTTCCTCAGCTCCAGGTGGATCC 256_61 TCGGTTGT ACAG TTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 192 NGSPLEx TCGCGAAAT CTCTG CTCGGAAGTAGCCCCCGTAGGTGCCCTGCTTGTGGTCAA 256_62 TCGGTTGT TGAG ACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 193 NGSPLEx TCGCGAAAT CACAC CGGGGGTAGCGGTCAATTCCAGCCACCAGAGCATGGCT 256_63 TCGGTTGT AGAG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 194 NGSPLEx TCGCGAAAT GTCAC GAAACATGATCGCTTATAAGCCAGCGGTCCCAATTCGGT 256_64 TCGGTTGT ACTG CCACCGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 195 NGSPLEx TCGCGAAAT GTGTG CCCACACGTCCATGACTGGTCGTCCTAGATTTTAGGTGT 256_65 TCGGTTGT ACAG CTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 196 NGSPLEx TCGCGAAAT CACAC CTTTAGCTCGAGATTGTCCCTCTCTGTCCAGCAGATAGG 256_66 TCGGTTGT ACAG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 197 NGSPLEx TCGCGAAAT CTCTC GCCGTCCTGCGCAAGCGCTTTTCAACCCCACTCCTTTCT 256_67 TCGGTTGT AGAG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 198 NGSPLEx TCGCGAAAT GACTG CAGTCTCTGGGAGAATGGGCAGTTCCCAATCTTGGCCCC 256_68 TCGGTTGT TGTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 199 NGSPLEx TCGCGAAAT GTCTG GGTTGGTGCTTGCCACACTTCTTACAGAAAGTCCGGCGG 256_69 TCGGTTGT TGTG GTTTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 200 NGSPLEx TCGCGAAAT GTGTC CATGTAGTTGAGGTCAATGAAGGGGTCATTGATGGCAAC 256_70 TCGGTTGT ACAG AATATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 201 NGSPLEx TCGCGAAAT CTCAC CGGAACTGGAGGTTTCCTTTTCCGCCATAGTTTGTCCTG 256_71 TCGGTTGT TGTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 202 NGSPLEx TCGCGAAAT GTGTC TTGTAGTCTGAGAGAGTGCGGCCATCCTCCAGCTGTTTG 256_72 TCGGTTGT TCAG CCGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 203 NGSPLEx TCGCGAAAT GTCAG CTGCAGTGGCTTTAAACCCACAGTAGTAACCTGCAGGAT 256_73 TCGGTTGT TGTG CACACTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 204 NGSPLEx TCGCGAAAT CACTG CGAAGGACAGGTGGTCTCTTCGTTGGGACGTCCCCTTTG 256_74 TCGGTTGT TCTG CCAGCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 205 NGSPLEx TCGCGAAAT CAGTG AGCTTGGCTCCCTTCTTGCGGCCCAGGGGCAGCGCATG 256_75 TCGGTTGT AGAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 206 NGSPLEx TCGCGAAAT GTCTG TTCCGACATGTCCGCATTTTTGATCACGGCCTTTCGGTG 256_76 TCGGTTGT TGAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 207 NGSPLEx TCGCGAAAT CAGAG CTTGGGAAGACCAAGTCCTCAAGGATGGCATCGTGCACA 256_77 TCGGTTGT TCAG GCTGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 208 NGSPLEx TCGCGAAAT CTCTG CGGCCGCCTCCAGGAACGCCGACCACTCCACTTTAGGT 256_78 TCGGTTGT TCAG ATCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 209 NGSPLEx TCGCGAAAT GTCTC AGGCGAAGTTCCGTCTACGGCTATTTAATGGAGCGCCTG 256_79 TCGGTTGT TCTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 210 NGSPLEx TCGCGAAAT CTCTC TGTATGTTCCATCCATGTGAGCAGCAAATGTGTATTTCCC 256_80 TCGGTTGT TGAG ACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 211 NGSPLEx TCGCGAAAT CAGTC GGTCTCATCCGAACCCTGCGGATATATTTTTCACCCAAGA 256_81 TCGGTTGT TGAG AATTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 212 NGSPLEx TCGCGAAAT GACAC GGCCTTCACGCGGCCCAGGAGTTTCTTATTGTTGCGGCA 256_82 TCGGTTGT AGAG GTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 213 NGSPLEx TCGCGAAAT GTGAG CCTTTTCCAAGGATTTTACGTTGCGGCTTGTTAGGGTGAT 256_83 TCGGTTGT ACAG TTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 214 NGSPLEx TCGCGAAAT GTGTG ACTGTTCTCTCTTGGCAAAGTAATCAGGATACATTGCCTG 256_84 TCGGTTGT AGAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 215 NGSPLEx TCGCGAAAT GTCAC ACAGTAGCATGCAGTCCCACAACTTGTACCAGCATCCCC 256_85 TCGGTTGT TGTG AGCGTCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 216 NGSPLEx TCGCGAAAT GTCAG ACTTGGCTCCAGCATGTTGTCACCATTCCAACCAGAAATT 256_86 TCGGTTGT TCAG GGCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 217 NGSPLEx TCGCGAAAT GACTC ACAATGCAAAGATGGCTTTTCAGAGCAGCCAGTGGGGGT 256_87 TCGGTTGT AGAG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 218 NGSPLEx TCGCGAAAT CTGAG CGACGTAGCCCGGCCTCTTCGACCTGCACCTCCGCGGC 256_88 TCGGTTGT ACTG TCCCTCTGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 219 NGSPLEx TCGCGAAAT CTCTC AGTGGAAACAGGATTACTATGATACAAAACTTCCACTACT 256_89 TCGGTTGT ACTG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 220 NGSPLEx TCGCGAAAT GTGAC GCAAAGGCAATCTTCAAATAGAAGCTGGCAACACAAGAC 256_90 TCGGTTGT ACAG CTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 221 NGSPLEx TCGCGAAAT GTGTG AATCACGCACTGTCCCCAACAGCCCCAGTTAACACAGGG 256_91 TCGGTTGT TGTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 222 NGSPLEx TCGCGAAAT CTCAG CAGGGTTTCTGGTCCAAATAGGCTTGGTCTTGTTTATGGT 256_92 TCGGTTGT ACTG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 223 NGSPLEx TCGCGAAAT GTGTC CCCGAATCCGCCGGCCCTTCTCACCAAGAACATTCTGTT 256_93 TCGGTTGT TCTG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 224 NGSPLEx TCGCGAAAT GTCTC GGAGATCCATCATCTCTCCCTTCAATTTGTCTTCGATGAC 256_94 TCGGTTGT TCAG ATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 225 NGSPLEx TCGCGAAAT GACTC TGGCATTAGCAGTAGGTTCTTGTATTTGAGTCTGCTTGGT 256_95 TCGGTTGT ACTG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 226 NGSPLEx TCGCGAAAT CTCAC GAAAACTGGTCAGATGAATATTATTGCTTCCCATTTTCAA 256_96 TCGGTTGT AGTG CCAGTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 227 NGSPLEx TCGCGAAAT GACTC TCCAGAGGGTCCGGATCGCTCTCTTCTGCACTGAGGTTG 256_97 TCGGTTGT TGTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 228 NGSPLEx TCGCGAAAT CTCTG CCATCCTGGCAGGCGGCTGTGGTGGTTTGAAGAGTTTG 256_98 TCGGTTGT ACTG GACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 229 NGSPLEx TCGCGAAAT GTCAG GCTGGCAAGGCTGAGCAATTCATGTTTATCTGCAACAGC 256_99 TCGGTTGT TGAG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 230 NGSPLEx TCGCGAAAT GAGAG AGCATCAGCTACTGCCAGCGGTTCATGGGCTTCTTTTAC 256_100 TCGGTTGT ACTG TATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 231 NGSPLEx TCGCGAAAT CAGTC TGAGTGAGCCCTCCTGCCACGTCTCCACGGTCACCACCT 256_101 TCGGTTGT TCTG CCTCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 232 NGSPLEx TCGCGAAAT GTGAC CTTTGGGTCCCAAGGTGCTCTTTACCAAGTCTCCAATGG 256_102 TCGGTTGT AGAG CGATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 233 NGSPLEx TCGCGAAAT CAGTG AACCCAATTAGTTCCCAGAAGTCACAACTCAGCTCATGG 256_103 TCGGTTGT ACTG CCACCTGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 234 NGSPLEx TCGCGAAAT CACAC CTCCTTGGTTCCATCTCCCGTGGCATCGCTTCCCTCTCG 256_104 TCGGTTGT TGAG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 235 NGSPLEx TCGCGAAAT GAGTG TATTTCACCAGGCCGGCAAAGAATGGACGGTCCTTCAGG 256_105 TCGGTTGT AGAG TCAACGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 236 NGSPLEx TCGCGAAAT CTGTG CCCTCAGAGGACAGGGCGCGGTTGCTGGGTCATGAGCA 256_106 TCGGTTGT TCTG CCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 237 NGSPLEx TCGCGAAAT CTGTC CAGGCACCAGACCAAAGACCTCCTGCCCCACAGCAAATG 256_107 TCGGTTGT TGTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 238 NGSPLEx TCGCGAAAT CAGTG AGTTTCCTCTTCACTCAGCAGCATGTTGGGGATCCCGCG 256_108 TCGGTTGT AGTG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 239 NGSPLEx TCGCGAAAT GTCAC TCTGTGAGAAAACCTTGGAGAATCAATAATGGTGGATTCA 256_109 TCGGTTGT TGAG TTGATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 240 NGSPLEx TCGCGAAAT GAGAC GCTGTATCTGGTCCTGGCGGCCGGCTGTGATGTTTGACA 256_110 TCGGTTGT ACTG TTGTCCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 241 NGSPLEx TCGCGAAAT CACTC GATGGCGGCGGGGGGCAGGGGGCGCACGTAGCCTGGC 256_111 TCGGTTGT TCTG CATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 242 NGSPLEx TCGCGAAAT GACTG CTCTCTCTTCAGCAATGGTGAGGCGGATACCCTTTCCTC 256_112 TCGGTTGT TGAG GGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 243 NGSPLEx TCGCGAAAT GTGTG TCTGGGACAAGACAGTCGAGGGAGCTTCTTCCTCAGGGA 256_113 TCGGTTGT ACTG ACTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 244 NGSPLEx TCGCGAAAT CAGAG GCTGCCAAAGCTGGGTCCATGACAACTTCTGGTGGGGC 256_114 TCGGTTGT AGTG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 245 NGSPLEx TCGCGAAAT GTCAG AGACTGCCAGCGAAGCCCCTCTTATGAGCAAAAGAGCAA 256_115 TCGGTTGT TCTG CCCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 246 NGSPLEx TCGCGAAAT CACTC CTTCAGGTGTCCTTGAAGCAATAATTTCTGTCAGTACTTT 256_116 TCGGTTGT TCAG TTCATTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 247 NGSPLEx TCGCGAAAT CTGTC AACGATCAAAATTAGACATGTCTTCATCTGAATCATCTTC 256_117 TCGGTTGT ACAG CCAGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 248 NGSPLEx TCGCGAAAT GTGAG CGGCCACACCATCTTTGTCAGCAGTCACATTGCCCAAGT 256_118 TCGGTTGT TGTG CTCCAACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 249 NGSPLEx TCGCGAAAT GAGTC TGACCTCTCACTTTTCCAGCACGGGCCAGGGAACCATGG 256_119 TCGGTTGT AGTG ACTTTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 250 NGSPLEx TCGCGAAAT GTGAC GTCAGCATAATCTTTATTTCAAAATAACATTTTTATTATGG 256_120 TCGGTTGT TGAG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 252 NGSPLEx TCGCGAAAT CTCAC AGCCACAGGATGTTCTCGTCACACTTTTCCATGTAGGCG 256_121 TCGGTTGT ACAG TTATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 253 NGSPLEx TCGCGAAAT GTCTG TATCCGTTCCTTACATTGAACCATTTTACTGTTCCCAAAAC 256_122 TCGGTTGT ACAG CTTCGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 254 NGSPLEx TCGCGAAAT CTGTC GACTTTTACAATCGATTCCCCAAACCCCTTTATGGCAGCA 256_123 TCGGTTGT AGTG ACACTGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 255 NGSPLEx TCGCGAAAT GACAC TTCTTGTAATTTGCATAATCCTCAAGAATGGAATCCACTG 256_124 TCGGTTGT TGAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 256 NGSPLEx TCGCGAAAT GAGAG TGGTCCCAGGGGAAAGGAAGAGGCCAGTTGGTCCAGTT 256_125 TCGGTTGT AGAG TTGATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 257 NGSPLEx TCGCGAAAT GACTG CAGGGGACGGTACTCCACATCCTCTCTGAGCAGGCGGT 256_126 TCGGTTGT ACTG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 258 NGSPLEx TCGCGAAAT CTCTG CTTCTACATCATCAGCTGCCATACGAAGAAGGGACTCCG 256_127 TCGGTTGT AGTG TTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 259 NGSPLEx TCGCGAAAT GACTG GCCACCAGCATCAACCTTCTTGGCTTCGGGTTTCTTCTG 256_128 TCGGTTGT ACAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 260 NGSPLEx TCGCGAAAT GTCTG CCCCACCGGTGCTCTTGGTACGAAGATCCATGCTAAATT 256_129 TCGGTTGT AGAG CCCCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 261 NGSPLEx TCGCGAAAT CAGAG TTGTATATAAGATTACTTTATTCCTGCATCTTCTCAATGGT 256_130 TCGGTTGT TGAG TTCTTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 262 NGSPLEx TCGCGAAAT GACAG CATTTTCATGGTTTTGTAGAGCTTCAATTTTGTCTAAGCCT 256_131 TCGGTTGT ACTG CCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 263 NGSPLEx TCGCGAAAT GTGAC CATAGTTGTCAACAAGCACAGTGAAAGCGCCATTCTCTTT 256_132 TCGGTTGT TGTG ACATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 264 NGSPLEx TCGCGAAAT GTCTC GCCAACAGCATGCTGGGTAACATTGTAGACTCTTCCTGG 256_133 TCGGTTGT AGTG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 265 NGSPLEx TCGCGAAAT CTGAC AGGAGATCTCCACAGGGGCTGGACGGTTCATTATGGCAA 256_134 TCGGTTGT AGAG ATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 266 NGSPLEx TCGCGAAAT CTGAG TTGAGCATCTCGTAGTTGGGAGGCTGGCCGCTGTTGACA 256_135 TCGGTTGT TCAG GGAGAGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 267 NGSPLEx TCGCGAAAT CAGAC CTCCCTTTCCCCAGTAGTTTCGGTTTCTCAACAGTTTCCT 256_136 TCGGTTGT TGTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 268 NGSPLEx TCGCGAAAT GTGAG TGGTTTTTAACAGGTTTAACCAATCATCTACTATCTGATTG 256_137 TCGGTTGT ACTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 269 NGSPLEx TCGCGAAAT CTGAC CCTTCTGTCCTCATGTTGGCAGAGATATCTACTCTGTGGT 256_138 TCGGTTGT AGTG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 270 NGSPLEx TCGCGAAAT GACAG GGATTCCAGTAGCCAGGTTGGTACGGGACGGCATCATAA 256_139 TCGGTTGT AGAG CATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 271 NGSPLEx TCGCGAAAT CTGAG CTTCAGCGGAGGCATTTCCACCAATGAGCGAGTCATTGG 256_140 TCGGTTGT AGTG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 272 NGSPLEx TCGCGAAAT GTCAG GTTTATGGTAAAGCTTAGCCTTCAGACCAATCATTTTCTTT 256_141 TCGGTTGT ACAG GCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 273 NGSPLEx TCGCGAAAT CTCAC GGCCGCAAAAGGGAAGAGAACTACACGCTGCTTCCGGT 256_142 TCGGTTGT TCTG TCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 274 NGSPLEx TCGCGAAAT GAGTG TTGTTCACTGGGTCTTTGTCTTTCTTGGCCGACTTTCCAG 256_143 TCGGTTGT TGAG CGTCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 275 NGSPLEx TCGCGAAAT GAGAC CTTCCCAGTTAAGGCTCTTTATTTTATTTTGAACACTTTTT 256_144 TCGGTTGT AGTG TGCATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 276 NGSPLEx TCGCGAAAT CAGAC ATCAACAAGCCACGGTTTTAGCTCTTCAGGAATCTTTACT 256_145 TCGGTTGT ACAG TTAACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 277 NGSPLEx TCGCGAAAT CACAC GGTGGTTCCTTGAGGGCTTTGATGATCAGGGCAGAGGC 256_146 TCGGTTGT TCTG AGAAGGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 278 NGSPLEx TCGCGAAAT GTGTC AATTCACACACCTCACAGTAAACATCAGACTTTGCTGGGA 256_147 TCGGTTGT AGTG CCTCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 279 NGSPLEx TCGCGAAAT GTCTG TGTCATCCTTCTTGCCACCTCCAGGACCATGACCACCAC 256_148 TCGGTTGT ACTG TCTGACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 280 NGSPLEx TCGCGAAAT GTGAG GAGCAAGGAGGGCTGGAAGCTGTTAGTCAGAGTGTTGA 256_149 TCGGTTGT TCTG AGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 281 NGSPLEx TCGCGAAAT CACAC AAAATTGTGCGGATGTGGCTTCTGGAAGACCTTCATTCTA 256_150 TCGGTTGT TCAG AAGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 282 NGSPLEx TCGCGAAAT CACTG GCAGTTTTCTAATTGAGAATGTAATCTTGGTCTTTAAAGA 256_151 TCGGTTGT TGTG ACATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 283 NGSPLEx TCGCGAAAT CACAC GTTTCTGCATCAGCCCGCTCATCAAATCCAGGGAAGTTG 256_152 TCGGTTGT ACTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 284 NGSPLEx TCGCGAAAT CTGAG CCAGCGGCAACCTCAGCCAAGTAACGGTAGTAATCTCCT 256_153 TCGGTTGT TCTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 285 NGSPLEx TCGCGAAAT GACAC GTGATCGGGGTTTCTTGATACCATTTCTGTGCCATTTTCG 256_154 TCGGTTGT TGTG GGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 286 NGSPLEx TCGCGAAAT GTCAC AGGAGGTCCTGCTGAGTTGGTGAATCTCTGGTAACGGTG 256_155 TCGGTTGT AGAG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 287 NGSPLEx TCGCGAAAT CTGAG CCTGGTTTTCTAAAATTCTTCAGGTCAATAGTCAAGCCTT 256_156 TCGGTTGT TGAG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 288 NGSPLEx TCGCGAAAT CTGAC ACAATATCACCTTTCTTATAGATTCGCATATATGTGGCCA 256_157 TCGGTTGT ACAG AAGGATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 289 NGSPLEx TCGCGAAAT CTCTG AAACAAAACAAGAAAAAGTAATCTGCTAAAAACTATAGGG 256_158 TCGGTTGT TGTG TCCCCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 290 NGSPLEx TCGCGAAAT CAGTG TAGAATCTTTTTTATTCAGAAAAAAAAAACCCCAAAAAACA 256_159 TCGGTTGT ACAG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 291 NGSPLEx TCGCGAAAT CTGTG AGTTTAATAAATACAAATACTCGTTTCTTTTTGATTAGTGT 256_160 TCGGTTGT AGAG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 292 NGSPLEx TCGCGAAAT GTGAC ACTTTGAGATTCTTTTCTTTTGCGCCTCTTATCAAGTCAG 256_161 TCGGTTGT TCAG CTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 293 NGSPLEx TCGCGAAAT CACAG AGCCTGGTTGGAGGATTCCTAGTTTTATACATGAGAAATA 256_162 TCGGTTGT AGAG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 294 NGSPLEx TCGCGAAAT GAGTC GTTCCCAAGATAGAAGAGTAGGTATGAAGCAATTCTGAC 256_163 TCGGTTGT AGAG TCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 295 NGSPLEx TCGCGAAAT GACTC TCTTTGTATGAGTCTTCATTCAGTGTATCAAGTTCATGGT 256_164 TCGGTTGT AGTG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 296 NGSPLEx TCGCGAAAT CTGTG ACAGATGAATGTAGGATTGATGCAAGTCACTTCCAGGAA 256_165 TCGGTTGT ACTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 297 NGSPLEx TCGCGAAAT GTGAG TCGCTTTTAGCTCCTCGAGTTTCTTCTGCTCCTCTTTTTGT 256_166 TCGGTTGT TGAG TTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 298 NGSPLEx TCGCGAAAT CTCAG TACTTCTGGGCCGTCACAGGGGAGGGCAGGTGGATGGT 256_167 TCGGTTGT AGTG GATCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 299 NGSPLEx TCGCGAAAT CACTC TGGTGCCGGATGAACTTCTTGGTTCTCTTTTTGACGATCT 256_168 TCGGTTGT ACTG TGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 300 NGSPLEx TCGCGAAAT GAGTC TATGCCTAGAACTTTCACGCCAATTATTTCACCTCTTGCA 256_169 TCGGTTGT TGAG CATATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 301 NGSPLEx TCGCGAAAT CACAG CCCAGGTCCTGTGATGTTTATTGAAGGAAGCAAGGGCAG 256_170 TCGGTTGT TCTG GGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 302 NGSPLEx TCGCGAAAT CAGAC GTCCCTTTGTTTTCTTCTTCTTTTTCCCCACTCTAGTTGGT 256_171 TCGGTTGT AGTG ACAGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 303 NGSPLEx TCGCGAAAT CAGAC CCATCGATGTTGGTGTTGAGTACTCGCAAAATATGCTGG 256_172 TCGGTTGT TCTG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 304 NGSPLEx TCGCGAAAT GTGTG GATACCACAGAATCAGCAGGGTGAGAAACAATTGCACAA 256_173 TCGGTTGT TCTG AAGACTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 305 NGSPLEx TCGCGAAAT GACTC AAAGCTTGAGATCACTTGAGGCCAGAGTTTTCAGACCTG 256_174 TCGGTTGT TCTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 306 NGSPLEx TCGCGAAAT GACAG CGGGTGTGGACGGGCGGCGGATCGGCAAAGGCGAGGC 256_175 TCGGTTGT TCTG TCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 307 NGSPLEx TCGCGAAAT CACAG CAGCGCGAGTGCAGAGCATGGTGGTAGATGTGGCAGAG 256_176 TCGGTTGT ACAG GATGGCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 308 NGSPLEx TCGCGAAAT CTGAG GACCCTCATAGACAGCAGACAGAAGAGGAGTAATATGAT 256_177 TCGGTTGT TGTG GTTTATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 309 NGSPLEx TCGCGAAAT GTGTG AAATACACTTTTAATTGATTTCAGATAAAAACTACTTGGTC 256_178 TCGGTTGT AGTG GGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 310 NGSPLEx TCGCGAAAT GTGAG GCCGCGCGAAGCCGGAGAGGAGAAGAAGAGAAGGAGG 256_179 TCGGTTGT TCAG GTTAGGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 311 NGSPLEx TCGCGAAAT CAGTC CAAATCTCAGGGAAGCAGTGATGGAGGACACAATCTGGC 256_180 TCGGTTGT ACTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 312 NGSPLEx TCGCGAAAT CACTC GGTCATAGTGGAGGGTAAGAGCTTTTACATCCCGCAGTG 256_181 TCGGTTGT TGTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 313 NGSPLEx TCGCGAAAT CACAG GATCCATCATTTCTCCTTTAAGCTTATCTTCCAAAATGGTC 256_182 TCGGTTGT TGTG GGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 314 NGSPLEx TCGCGAAAT GTCTG TGTTTACTGATTTCTGTCTGGTTAAACATCCAATACTGGT 256_183 TCGGTTGT TCAG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 315 NGSPLEx TCGCGAAAT GACAG GCCTATCTCTTTCCATCAGACTCCAGTGATACCCAATGGT 256_184 TCGGTTGT TCAG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 316 NGSPLEx TCGCGAAAT GACAG CCTGTAATCTCAGCACGTTGGGAGGCGAGGTGGGTGGA 256_185 TCGGTTGT AGTG TGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 317 NGSPLEx TCGCGAAAT CTCTC CTTAAATACCAGATACATTTTTAGTCCTCTACATAATGGTC 256_186 TCGGTTGT ACAG GGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 318 NGSPLEx TCGCGAAAT GACAC GTTTTTTGGAAGATTCGGGTTCAGCACAGGATTCCATTTG 256_187 TCGGTTGT AGTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 319 NGSPLEx TCGCGAAAT GTCTC TGATATCCTTGTTTTTAACTGTTGTGGCTTGCTGAATCAA 256_188 TCGGTTGT AGAG ATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 320 NGSPLEx TCGCGAAAT CAGAG AAGACGGAGTAGTTAAGAGCCAGGCCTAATCGGATGGTG 256_189 TCGGTTGT ACAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 321 NGSPLEx TCGCGAAAT CTGTC CGAGTTCCAGAGACAATATCAAAATTACCCTCCTTTTGGT 256_190 TCGGTTGT ACTG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 322 NGSPLEx TCGCGAAAT CTCTG GGTGAGAGAACTAATAGCAACCAGGCAACTGAGGACGAA 256_191 TCGGTTGT TCTG GTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 323 NGSPLEx TCGCGAAAT CTCAC TTGGGGTGCTTTATCTTCTTTGAGTTTTCGCACAAGATGG 256_192 TCGGTTGT ACTG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 324 NGSPLEx TCGCGAAAT CTGTG GGGCATGGGCTCACATTCACTTCCTTTATAACTCCATCCT 256_193 TCGGTTGT TGTG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 325 NGSPLEx TCGCGAAAT CAGTC GCCTGTTTTCCCTTTGCTCCCCTTTTCCCTTTTGTTTGCA 256_194 TCGGTTGT TCAG CTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 326 NGSPLEx TCGCGAAAT GAGAC CATTTTTCCGATAGTTAATAGTAATGGAGTAATAATGTTG 256_195 TCGGTTGT TCTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 327 NGSPLEx TCGCGAAAT GTGAC CACTTGGCCCTTTCTCTTCTTATCTCCTCCCAGTTCTGGT 256_196 TCGGTTGT TCTG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 328 NGSPLEx TCGCGAAAT GACTG TCGTCCTCCTCCTCTTCATCCACACCATCCACCTCGGTG 256_197 TCGGTTGT TCAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 329 NGSPLEx TCGCGAAAT GACAG CCTCCTCTTCCTCCCCACCTTCTTCCTCTTCTTCGTCTAC 256_198 TCGGTTGT TGAG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 330 NGSPLEx TCGCGAAAT GACTG ACGATGGCGGAGAAAGGAAGAGGAGGGAAGCTGGCGG 256_199 TCGGTTGT AGAG AATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 331 NGSPLEx TCGCGAAAT GAGAG TATAATACAAAAAAAGACCAAAAAACAAAACAAAACAAAA 256_200 TCGGTTGT ACAG CATCAATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 332 NGSPLEx TCGCGAAAT CTCAC AACACAAGTGTGTTGTTGTCTTCTATCTTCTTCATGGCAT 256_201 TCGGTTGT TGAG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 333 NGSPLEx TCGCGAAAT GAGTG ACCAAAACCACAATTTCTGCAGTTTAAAATGTTTCACTTG 256_202 TCGGTTGT ACAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 334 NGSPLEx TCGCGAAAT CACAG CCGCTGCTCGGTCCCCCAGGCCCCGCCGTCCTTGCTGT 256_203 TCGGTTGT AGTG TTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 335 NGSPLEx TCGCGAAAT GACTG CGAGATCCTGGTGCTCCCACTCGCGTTGCTGCAGCAAGA 256_204 TCGGTTGT AGTG AATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 336 NGSPLEx TCGCGAAAT CACTG GCCGGCCGGGGTGGGGAACGAGCGCCGGGTTCCGTCC 256_205 TCGGTTGT TCAG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 337 NGSPLEx TCGCGAAAT GTCAG TCTCTGCCACCGCTGGTGCTGCTGTCTCCCACTCGGTGG 256_206 TCGGTTGT AGTG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 338 NGSPLEx TCGCGAAAT CTGTG CATCGAAGACGCTCGCTTCAGAAATGTCCCTGACTGCTG 256_207 TCGGTTGT AGTG CGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 339 NGSPLEx TCGCGAAAT CTGAC GTCTTTCAGGTCAATGTAGTGCTGCTTCAGGTGTTCTTCA 256_208 TCGGTTGT ACTG GAGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 340 NGSPLEx TCGCGAAAT CTGTC CATCAGCATAGCCTCCGATGACCATGGTGTTCCACAAAG 256_209 TCGGTTGT TGAG GGTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 341 NGSPLEx TCGCGAAAT CACTG GATGCCCAGAATCAGGGCCCAGATGTTCAGGCACTTGG 256_210 TCGGTTGT ACTG CGGTGGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 342 NGSPLEx TCGCGAAAT CAGTG AGAACCGGAAGAGAAAGGGGCTGCGGTGCAGCACGGGA 256_211 TCGGTTGT TCAG AATAGGGTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 343 NGSPLEx TCGCGAAAT GTGAG CCCCCCAACCCTCACTGTTTCCCGTTGCCATTGATGGTG 256_212 TCGGTTGT AGAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 344 NGSPLEx TCGCGAAAT CACTG ACCTCATAGGTGCCTGCGTGGGCGCTCTTGTGGTCCAG 256_213 TCGGTTGT ACAG GCTCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 345 NGSPLEx TCGCGAAAT GAGAC ACAGGAGTCTTGCCCAAGCCCTGTCATGTCAGTGTGTGT 256_214 TCGGTTGT TGTG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 346 NGSPLEx TCGCGAAAT CAGTG CTTCTTCAAGGTGATATAGACGCTGCCCGACGTCCGGTG 256_215 TCGGTTGT TCTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 347 NGSPLEx TCGCGAAAT GTGTC GCCATCTGGGCCATCAGACCTGGCTGCCGGGGCGCATG 256_216 TCGGTTGT TGAG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 348 NGSPLEx TCGCGAAAT GACTC GCTTCTTGGGAAATGAAGCCACAGCCAGCTCATATATGT 256_217 TCGGTTGT TGAG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 349 NGSPLEx TCGCGAAAT CAGAG CTCATCCACGATGGCTGCTATCGGTAAACAGTTAAAACA 256_218 TCGGTTGT TCTG GTCTGTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 350 NGSPLEx TCGCGAAAT GTCAG TGACCCGCTCGATCGGAGCCACGGCCGTCTTGGAGATG 256_219 TCGGTTGT AGAG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 351 NGSPLEx TCGCGAAAT CAGTC GGGTGATCAGCTGTGAGGCATTGAACTTGGCCACCACAC 256_220 TCGGTTGT AGTG TCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 352 NGSPLEx TCGCGAAAT GTGTC ACAGCACAGTAACAAAGTTATTAGGAAAACAGGACTACC 256_221 TCGGTTGT TGTG ACAAAGATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 353 NGSPLEx TCGCGAAAT CAGAC ACCAATGTTTTTTAGAATAGTGGCACCATCATTGGTTGGT 256_222 TCGGTTGT TGAG CGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 354 NGSPLEx TCGCGAAAT GACTG GCAGTTTACGCTGTCTAGCCAGAGTTTCACCGTAAATATG 256_223 TCGGTTGT TCTG ATTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 355 NGSPLEx TCGCGAAAT GTCTC CACTCTTTCACTTAAAGAGATATAGCTAGAAGGATTCACA 256_224 TCGGTTGT ACAG GTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 356 NGSPLEx TCGCGAAAT GACAC ACCTTCAGGTCGTCCAGCTGTTTCAGCAGCTCCTCCTGG 256_225 TCGGTTGT ACAG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 357 NGSPLEx TCGCGAAAT CACAG GCCGTCAACTTGCGTCGGAACATGGTCCCCGCTTCTCGC 256_226 TCGGTTGT TCAG TCTGGTCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 358 NGSPLEx TCGCGAAAT GTGAC CGATCCAAAAAGTGCGCGATGCGAGTAGTCAAGTCGTAC 256_227 TCGGTTGT ACTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 359 NGSPLEx TCGCGAAAT CTGTC AGACAATGGTCCCTCTATTTCAACACCTTTTTCGGTGACA 256_228 TCGGTTGT TCTG GTGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 360 NGSPLEx TCGCGAAAT GAGTC GGTGATCTTGCTCTTGCTCCTTTCGATGGTCACCACCCC 256_229 TCGGTTGT ACTG TCCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 361 NGSPLEx TCGCGAAAT CTCTC AACAGCCTTTAGTTCTACAGGAAATGGCACTGATGGACA 256_230 TCGGTTGT TGTG GAAGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 362 NGSPLEx TCGCGAAAT GAGAG CCGGCTGTCTGTCTTGGTGCTCTCCACCTTCCGCACCAC 256_231 TCGGTTGT TCTG CTCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 363 NGSPLEx TCGCGAAAT CTGAG GGGAGGTGAACCCAGAACCAGTTCCCCCACCAAAGCTG 256_232 TCGGTTGT AGAG TGGAAATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 364 NGSPLEx TCGCGAAAT GAGTG TCACAACAGGGGAGGCCTTGGTGAAAGCTGGGTGGAAA 256_233 TCGGTTGT AGTG ACCCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 365 NGSPLEx TCGCGAAAT CTGTG GTGGAGTCTAGAGGATCCACAGCTGGATAGATGCCCAG 256_234 TCGGTTGT ACAG CTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 366 NGSPLEx TCGCGAAAT CACTG AGGTAAAGGCCTGCAGCGATGAAACAGTTGTAGCTGACT 256_235 TCGGTTGT AGAG TGCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 367 NGSPLEx TCGCGAAAT CTCAG TCATTGATTGGTTGCCCGTCAAATCGGAATCTGATCTGCT 256_236 TCGGTTGT TCAG GGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 368 NGSPLEx TCGCGAAAT CTGTG GCTGAAACTTTCACAGGCTTCACAATCTTTTGCTTAGGTG 256_237 TCGGTTGT TGAG CTGCCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 369 NGSPLEx TCGCGAAAT GTGAC CACATAGAAGTCCAGGCCGTAGATACCAATGCTTGGTGG 256_238 TCGGTTGT AGTG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 370 NGSPLEx TCGCGAAAT CTGAC ACCATGCCCAGCACATCCTGCACATGCTGGCCCAGGTTG 256_239 TCGGTTGT TCAG GAGCCCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 371 NGSPLEx TCGCGAAAT GTCAG GGTGATGGTAGCCTTTCTGCCCAGCGCGTGCCACAGTG 256_240 TCGGTTGT ACTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 372 NGSPLEx TCGCGAAAT CACTG GCCGCATCCGCGTCAGATTCCCAAACTCGCGGCCCATTG 256_241 TCGGTTGT AGTG TGGCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 373 NGSPLEx TCGCGAAAT CTCAG TTGCTGTCACCAGCAACGTTGCCACGACGAACATCCTTG 256_242 TCGGTTGT AGAG ACAGACATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 374 NGSPLEx TCGCGAAAT CAGTC GCTGGTATAAGGTGGTCTGGTTGACTTCTGGTGTCCCCA 256_243 TCGGTTGT ACAG CGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 375 NGSPLEx TCGCGAAAT GAGAG CGGCATCCTCTCAGGAGGGCCGGTCCGGGTCTCAGCGC 256_244 TCGGTTGT AGTG GCCTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 376 NGSPLEx TCGCGAAAT CAGAC AGGTTAACCATGTGCCCGTCGATGTCCTTGGCGGAAAAC 256_245 TCGGTTGT AGAG TCGTGCATGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 377 NGSPLEx TCGCGAAAT GAGTC ACCACAAACTCTTCCACCAGCCAGCATGGCAAATTTGAG 256_246 TCGGTTGT TGTG GTGCTTGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 378 NGSPLEx TCGCGAAAT CTGAC TGGAGATTGCAGTGAGCTGAGATCACACCACTGGGCTCC 256_247 TCGGTTGT TCTG AGCCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 379 NGSPLEx TCGCGAAAT CAGTG GGCCAGTGGTCTTGGTGTGCTGGCCTCGGACACGAATG 256_248 TCGGTTGT TGTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 380 NGSPLEx TCGCGAAAT CACAG GCAGCTGGAGCATCTCCACCCTTGGTATTTCTGGTGTAA 256_249 TCGGTTGT ACTG TGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 381 NGSPLEx TCGCGAAAT CTCTC GTAGCTGGGGGTGCTGGGGTTCATTCTCGGCACGGCTG 256_250 TCGGTTGT AGTG CTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 382 NGSPLEx TCGCGAAAT GTCAC GCTGTAACCACACCGACGCGCGAGCTCTGCGCGGGCTT 256_251 TCGGTTGT AGTG CACTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 383 NGSPLEx TCGCGAAAT CTGTC TCCAGGTCGATCTCCAAGGACTGGACTGTACGTCTCAGC 256_252 TCGGTTGT AGAG TCTTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 384 NGSPLEx TCGCGAAAT GACAG TTAACCTACCACTGTTTTGTTTAGAGCGAACACAGTGTGG 256_253 TCGGTTGT TGTG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 385 NGSPLEx TCGCGAAAT GACAC TCTCCTCCAGGGTGGCTGTCACTGCCTGGTACTTCCATG 256_254 TCGGTTGT ACTG GTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 386 NGSPLEx TCGCGAAAT GAGTG CACGACAGCAAATAGCACGGGTCAGATGCCCTTGGCTGA 256_255 TCGGTTGT ACTG AAAGTGGTCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 387 NGSPLEx TCGCGAAAT GTCAC GGGACCAGCCGTCCTTATCAAAGTGCTCCCAGAAATTGG 256_256 TCGGTTGT TCAG TCGGTGCTCGCAGGCTCGGCA SEQ ID NO: 131 SEQ ID NO: 388 Name Region 1 Region 2 Capture CWSWSWS ACAACCGAATTTCGCGAT TTTTTTTTTT\Biotin Probe256 WS (SEQ ID NO: 389) plex

TABLE 3 List of sequences used for proof of concept experiment FIG. 6 Name Region 3 Region 4 Region 5 Pre- TAGCGCCT CTCTCT TAGCGCCTGCGGCCTGTCTCTCTCTGUAAACGCATCGG cursor GCGGCCT CTGU TCGAATTATCTCCTGCTAGGCACTCGCTGTGCCCTGGA Oligo 1 GT SEQ ID NO: CTATCGTAA000ATGCTGTTT/36-FAM-3′ SEQ ID NO: 391 SEQ ID NO: 392 390 Pre- TAGCGCCT GTGTGA CTTGCGGAACACGAATCGACCACTGACACAATTCGTAAT cursor GCGGCCT CTGU CTCATTGCAAGCGTTT/36-FAM-3′ Oligo 2 GT SEQ ID NO: SEQ ID NO: 394 SEQ ID NO: 393 390 Pre- TAGCGCCT CAGAGA ATGCCCATTCAGCCTCACGTGGTGCTGATTTGGGGTGT cursor GCGGCCT CTGU TT/36-FAM-3/ Oligo 3 GT SEQ ID NO: SEQ ID NO: 396 SEQ ID NO: 395 390 Name Region 1 Region 2 Capture CAGWSWS ACAGGCCGCAGGCGCTA/iBiodT/TTTTTTT/iBiodT/TTTTTTT/3B Probe256 WS (SEQ ID NO: 397) plex

TABLE 4 List of sequences used for FIG. 10 Name/ Region 6 7 8 Precur GTGGATGATC A

C UCGCTTCCATACCGGGCGATGGACACAATTAAGAT sor AACGC CGCATTTAGAGTGAAGTATCAATCGGAAATCGTGC Oligo 4 SEQ ID NO: 398 AGCGACC/36-FAM-3′ SEQ ID NO: 399 Precur GTGGATGATC A

C UCAATCAACCAGATTAGGACTCGGTTCCCGTGAGA sor AACGC AATAGAAGTCCGTATAAACGTTCAACGGGGTC/36- Oligo 5 SEQ ID NO: 398 FAM-3′ SEQ ID NO: 400 Precur GTGGATGATC A

C UCGCTTCCATACCGGGCGATGGACACAATTAAGAT sor AACGC CGCATTTAGAGT/36-FAM-3′ Oligo 6 SEQ ID NO: 398 SEQ ID NO: 401 Name/ Region 1 4 2 Capture GWSWSWST GCGTTGAT ATAGACTCG/iBiodT/TTTTTTT/iBiodT/TTTTTTT/3B Probe CATCCAC SEQ ID NO: 403 SEQ ID NO: 402 Name/ RegionS 5 3 Pro- AGTCTAT GTGGATGA tector TCAACGC SEQ ID NO: 398

All of the compositions and methods disclosed and claimed herein can be made and executed without undue experimentation in light of the present disclosure. While the compositions and methods of this disclosure have been described in terms of preferred embodiments, it will be apparent to those of skill in the art that variations may be applied to the compositions and methods and in the steps or in the sequence of steps of the method described herein without departing from the concept, spirit and scope of the disclosure. More specifically, it will be apparent that certain agents which are both chemically and physiologically related may be substituted for the agents described herein while the same or similar results would be achieved. All such similar substitutes and modifications apparent to those skilled in the art are deemed to be within the spirit, scope and concept of the disclosure as defined by the appended claims.

XI. REFERENCES

The following references, to the extent that they provide exemplary procedural or other details supplementary to those set forth herein, are specifically incorporated herein by reference.

-   SantaLucia Jr, J., & Hicks, D. (2004). The thermodynamics of DNA     structural motifs. Annu. Rev. Biophys. Biomol. Struct., 33, 415-440. -   Wu, L. R., Wang, J. S., Fang, J. Z., Evans, E. R., Pinto, A.,     Pekker, I., & Zhang, D. Y. (2015). Continuously tunable nucleic acid     hybridization probes. Nature methods, 12(12), 1191-1196. -   Zhang, D. Y., Chen, S. X., & Yin, P. (2012). Optimizing the     specificity of nucleic acid hybridization. Nature chemistry, 4(3),     208-214. 

1-81. (canceled)
 82. A method for generating a set of precursor oligonucleotide molecules, each comprising a target sequence, wherein each precursor oligonucleotide molecule comprises a fifth region that comprises the target sequence and a fourth region and a third region, wherein at least one of the fourth and third regions differs from any subsequence within the target sequence, the method comprising: (a) calculating for each of the precursor oligonucleotide molecules a standard free energy of hybridization between the precursor oligonucleotide molecule and (i) a first oligonucleotide comprising a second region that is complementary to the third region of the precursor oligonucleotide molecule, and (ii) a first region that is complementary to the fourth region of the precursor oligonucleotide molecule; (b) calculating a standard free energy of a capture reaction as the standard free energy of hybridization between each of the precursor oligonucleotide molecules and the first oligonucleotide and the standard free energy of hybridization between the first oligonucleotide and the target sequence; (c) rejecting the set of precursor oligonucleotide molecules if the standard free energy of the capture reaction does not meet a certain criterion; (d) repeating steps (a) to (c) until a set of precursor oligonucleotide molecules meets the criterion; and (e) producing the set of precursor oligonucleotide molecules.
 83. The method of claim 82, wherein the criterion is a negative free energy.
 84. The method of claim 82, wherein the method is a method for producing a set of precursor oligonucleotide molecules comprising a plurality of barcode sequences, wherein the third region is conserved across all precursor oligonucleotide molecules, and wherein the fourth region is unique for each precursor oligonucleotide molecule in the set of precursor oligonucleotide molecules; the method comprising: (a1) calculating for each precursor oligonucleotide molecule a standard free energy of hybridization between the precursor oligonucleotide molecule and (i) a first oligonucleotide comprising a second region that is complementary to the third region of the precursor oligonucleotide molecule, and (ii) a first region that is complementary to the fourth region of the precursor oligonucleotide molecule; (a2) calculating a standard free energy of hybridization of folding for each precursor oligonucleotide molecule and for each first oligonucleotide; (b) calculating a standard free energy of a capture reaction as the standard free energy of hybridization between the precursor oligonucleotide molecule and the first oligonucleotide and the standard free energy of folding of the first oligonucleotide and the standard free energy of folding of the precursor oligonucleotide molecule; (c) rejecting the set of precursor oligonucleotide molecules if the standard free energy of the capture reaction for any precursor oligonucleotide molecules exceeds a certain criterion; (d) repeating steps (a) to (c) until a set of precursor oligonucleotide molecules meets the criterion; and (e) producing said set of precursor oligonucleotide molecules.
 85. The method of claim 84, wherein the criterion is a maximum range of no more than 5 kcal/mol between a lowest standard free energy of capture and a highest standard free energy of capture for the set of precursor nucleotide sequences.
 86. The method of claim 84, wherein the fourth region is defined as a barcode sequence of length n.
 87. A capture probe library comprising: a plurality of oligonucleotides comprising a first plurality of oligonucleotides, wherein each oligonucleotide of the first plurality of oligonucleotides comprises: a first region comprising a first nucleotide sequence comprising at least 3 variable positions, wherein each variable position comprises a nucleotide selected from at least two possible nucleotides, wherein the first nucleotide sequence comprising at least 3 variable positions is unique to each oligonucleotide, and a second region comprising a second nucleotide sequence.
 88. The capture probe library of claim 87, further comprising a second plurality of oligonucleotides, wherein each oligonucleotide in the second plurality of oligonucleotides comprises a third region, wherein the third region is complementary to the second region.
 89. The capture probe library of claim 88, wherein a concentration of a second oligonucleotide is greater than a sum of the concentrations of each oligonucleotide of the first plurality of oligonucleotides.
 90. The capture probe library of claim 87, wherein the first nucleotide sequence further comprises an “S” degenerate nucleotide at one or more of the variable positions and/or a “W” degenerate nucleotide at one or more of the variable positions, but does not comprise an “N” degenerate nucleotide at any position, wherein the length of the first nucleotide sequence is between 5 and 50 nucleotides, wherein the number of variable nucleotides is between 3 and 30, and wherein the length of the second nucleotide sequence is between 5 and 50 nucleotides.
 91. The capture probe library of claim 87, wherein the second nucleotide sequence of the second region is conserved across each oligonucleotide in the first plurality of oligonucleotides.
 92. The capture probe library of claim 87, wherein the second nucleotide sequence comprises an “S” degenerate nucleotide at one or more position and/or a “W” degenerate nucleotide at one or more position, but does not comprise a “N” degenerate nucleotide at any position.
 93. The capture probe library of claim 87, wherein the standard free energies of binding between each oligonucleotide in the first plurality of oligonucleotides and a DNA sequence complementary to the entire sequence of the respective oligonucleotides in the first plurality of oligonucleotides are within 5 kcal/mol of each other.
 94. An oligonucleotide library comprising: (a) the set of precursor oligonucleotide molecules generated by claim 84, wherein the fourth region comprises a barcode sequence comprising a nucleotide sequence of n nucleotides in length, wherein the barcode sequence of each species of precursor oligonucleotide molecule is different, wherein 2n is greater than or equal to the number of unique target sequences, wherein the fifth region comprises a target sequence that is unique among the species of precursor oligonucleotide molecules in the set; and (b) a capture probe library of claim 91, wherein the first region comprises a nucleotide sequence of n nucleotides in length, wherein each nucleotide in the nucleotide sequence of n nucleotides in length is selected from two or more nucleotides, wherein the first region is unique among the species of capture probe in the plurality, wherein the second region is complementary to the third region, and wherein the fourth region of each species of precursor molecule is complementary to the first region of a species of capture probe.
 95. An aqueous solution comprising an oligonucleotide library of claim
 94. 96. A method for producing an oligonucleotide library comprising a plurality of distinct target oligonucleotides each having a specified sequence, the method comprising: (a) obtaining the set of precursor oligonucleotide molecules generated by claim 84, wherein the fourth region comprises a barcode sequence comprising a nucleotide sequence of n nucleotides in length, wherein the barcode sequence of each species of precursor oligonucleotide molecule is different, wherein 2n is greater than or equal to the number of unique target sequences, wherein the fifth region comprises a target sequence that is unique to the species of precursor oligonucleotide molecules in the set; (b) obtaining a capture probe library of claim 91, wherein the first region comprises a nucleotide sequence of n nucleotides in length, wherein each nucleotide in the nucleotide sequence of n nucleotides in length is selected from two or more nucleotides, wherein the first region is unique to the species of capture probe in the plurality, wherein the second region is complementary to the third region, and wherein at least one first region is complementary to a fourth region; (c) mixing the precursor oligonucleotide molecules obtained in step (a) and the capture probe library obtained in step (b) in an aqueous hybridization buffer; (d) removing precursor oligonucleotide molecules not bound to the capture probes; and (e) enzymatically or chemically cleaving the fifth region from the remaining precursor oligonucleotide molecules, thereby obtaining an oligonucleotide library comprising a plurality of distinct target oligonucleotides each having a specified sequence.
 97. A method for purifying one or more target nucleic acid molecules from a sample comprising a set of species of precursor oligonucleotide molecules, wherein each species of precursor oligonucleotide molecule comprises a fifth region comprising a target sequence, a fourth region comprising a sequence unique to the species of precursor oligonucleotide molecule in the set, wherein the fourth region is a barcode sequence of length n, wherein 2n is greater than or equal to the number of unique target sequences, and a third region that is conserved across all precursor oligonucleotide molecules in the set, the method comprising: (a) contacting the sample with a capture probe library of claim 91 at temperature and buffer conditions to allow for hybridization, wherein the first region comprises a nucleotide sequence of n nucleotides in length, wherein each nucleotide in the nucleotide sequence of n nucleotides in length is selected from two or more nucleotides, wherein the first region is unique among the species of capture probe in the plurality, wherein the second region is complementary to the third region, and wherein the fourth region of each species of precursor molecule is complementary to the first region of a species of capture probe (b) separating the plurality of species of precursor oligonucleotide molecules hybridized to the plurality of capture probes from the species of precursor oligonucleotides not hybridized to the plurality of capture probes; (c) treating the plurality of species of precursor oligonucleotide molecules hybridized to the plurality of capture probes with a cleavage agent sufficient to site-specifically cleave the plurality of species at a site to separate the fifth regions from at least a portion of the third and fourth regions; and (d) recovering the fifth regions from the plurality of capture probe species and at least a portion of the third and fourth regions, thereby producing one or more purified target nucleic acid molecule.
 98. The method of claim 97, wherein the set of species of precursor oligonucleotide molecules is a set of precursor oligonucleotide molecules produced by the method of claim
 86. 99. The method of claim 97, wherein each capture probe species further comprises a second oligonucleotide comprising a ninth region, wherein the ninth region is complementary to the second region.
 100. The method of claim 99, wherein each first oligonucleotide further comprises a seventh region, wherein each second oligonucleotide further comprises an eighth region, and wherein the seventh region is complementary to the eighth region.
 101. A method for purifying multiple target sequences from a sample comprising a plurality of precursor oligonucleotide molecules each comprising a target sequence region and a non-target sequence region, wherein each precursor oligonucleotide molecule comprises a different target sequence region, the method comprising: (a) providing a plurality of capture probes, wherein each capture probe has (i) a first region having a sequence that is complementary to the non-target sequence region of one of the precursor oligonucleotide probes and (ii) a first moiety sufficient to allow for isolation of the capture probe; (b) adding the plurality of precursor oligonucleotide molecules to a sample comprising the plurality of capture probes under conditions sufficient to promote hybridization of each capture probe to the non-target sequence region of the precursor oligonucleotide molecules complimentary thereto, thereby forming a plurality of capture probe-precursor oligonucleotide molecule complexes; and (c) isolating the plurality of capture probe-precursor oligonucleotide molecule complexes using the first moiety, thereby purifying the unhybridized precursor oligonucleotide molecules from the capture probe-precursor oligonucleotide molecule complexes. 